_4_95_2.pdf · MADICA 2014 - PROGRAMME Mercredi 5 Novembre 2014 9h00 Ouverture officielle 9h30 Conférence plénière I Anthony TURNER, Professor, Linköping (Suède) Printed Biosensor

MADICA 2014 - PROGRAMME Mercredi 5 Novembre 2014

9h00 Ouverture officielle

9h30 Conférence plénière I

Anthony TURNER, Professor, Linköping (Suède) Printed Biosensor Systems for Decentralised Diagnostics

10h00 Conférence plénière II

Prof. H. BOUCHRIHA (Université de Tunis) Cristaux photoniques et méta- matériaux

10h30Conférence plénière III

Dr Isabelle BERBEZIER (IM2NP, Univ. Aix-Marseille) Synthèse et auto-organisation des nanofils coeur-coquille Si-Ge

11h00 Pause-Café

Session A1 : Photovoltaique et Cellules solaires I

11h30 A11. R. Benabderrahmane Zaghouani, L. Manai, B. Dridi Rezgui and B. Bessaïs (Research and Technology Center of Energy, Borj-Cedria) Electroless metal deposition of Silver nanoparticles on silicon for photovoltaic applications

11h50 A12. A. Hadri, C. Nassiri, M.Loghmarti, FZ. Chafi and A. Mzerd (Fac. Sci. Rabat)

Preparation and characterization of (In-F) co-doped ZnO thin films for solar cells

Session B1 : Biocapteurs I

11h30 B11. C. M.A. Brett, M. M. Barsan, M. Emilia Ghica (Univ. Coimbra) NEW NANOSTRUCTURED MATERIALS FOR SENSORS AND BIOSENSORS

11h50 B12. A. Attar, L. Cubillana-Aguilera, I. Naranjo-Rodríguez, J. L. Hidalgo-Hidalgo de Cisneros , J. M. Palacios-Santander, A. Amine (Univ. Hassan II Mohammedia, Univ. Cadiz). A NOVEL AMPEROMETRIC INHIBITION BIOSENSOR BASED ON PEROXIDASE AND GOLD SONO-NANOPARTICLES IMMOBILAZED ONTO SONOGEL-CARBON ELECTRODE FOR THE DETERMINATION OF

12h10 A13. M. Bouzitoun, G. Hamdoun, S. Saidi and A. Belhadj Mohamed (CRTE Hammam Lif) Effect of the carbon nanotube concentration on dielelectrical behavior of (SWCNTs/PVDF) composites

SULFIDES

12h10 B13. PROKOPIV T., SMUTOK O., A. ERRACHID, GONCHAR M. (NAS Ukraine, Univ. Lyon)TESTING THE METAL-BIORECOGNIZING ABILITY OF DESFERAL TO BE USED IN BIOSENSORICS

12h30 Repas

Session A2 : Nouveaux matériaux et Cellules solaires II

14h00 A21. Conférence-clé L. Favre, A. Mansour, E. Gomes, G. Amiard, A. Ronda, I. Berbezier, V. Morin, A. Delobbe, P. Sudraud, M. Bollani, R. Sordan (IM2NP, Univ. Aix-Marseille) Auto-organisation de nanocristaux par démouillage de films minces silicium et germanium, sur substrats pré-gravés

14h30 A22. K. Omri, I. Najeh, R. Dhahri, J. El Ghoul, L. El Mir (Univ. Gabès, IMSIU Riyadh) Temperature effect on morphology and optical properties of ZnO nanoparticles synthesized by sol-gel method 14h50 A23. M. Mostefaoui, H. Mazari, S. Khelifi, A. Bouraiou, R. Dabou (Univ. Sidi-bel-Abbès) Effects of aerosols and dust deposition on the Performance of Photovoltaic Modules in the Saharan region

15h10 A24. J. Ghnimi, M. Ben Karoui, Z. Kaddachi, R. Gharbi (Univ. Tunis, CRTEn)) Flexible dye sensitized solar cells based on TiO2 nanoparticles

15h30 A25. S. Saadaoui, A. Torchani, T. Azizi, R. Gharbi (Univ. Tunis) Improvement in spectral response of dye-sensitized solar cells

Session B2 : Biocapteurs II

14h00 B21. Conférence-clé F. Lagarde (Univ. Lyon) Conception et caractérisation de nouvelles biointerfaces nanostructurées pour l’élaboration de biocapteurs électrochimiques ultrasensibles

14h30 B22. A. Miodek, M. Gomgnimbou, C. Sola, H. Korri-Youssoufi (Univ. Paris Sud) Elaboration de nanomatériaux à base de nanotube de carbone/polypyrrole/poly (amidoamine) dendrimères G4: plate-forme pour la détection ultrasensible d'ADN

14h50 B23 M. T. Zhybak, L. Y. Fayura, Y. R. Boretsky, M. V. Gonchar, A. A. Sibirny, E. Dempsey, Y. I. Korpan (NAS Ukraine, ITT Dublin) NOVEL L-ARGININE-SELECTIVE AMPEROMETRIC SENSOR BASED ON RECOMBINANT ARGININE DEIMINASE AND PLATINUM SCREEN-PRINTED ELECTRODES

15h10 B24. C. Durrieu, Y. Ferro, M. Perullini, S.A. Bilmes (ENTPE Lyon, Univ. Buenos Aires) Conception d’un biocapteur optique à micro-algues encapsulées dans un matériau

15h30 B25. M. Marrakchi, X. Liu, D. Xu, H. Dong, S. Andreescu (Univ. Clarkson, INSAT) Ultrasensitive antimicrobial peptide-based impedimetric sensor for the detection of bacteria

15h50 A26. N. JABALLAH, J.L. FAVE, M. MAJDOUB (Univ. Monastir, UPMC Paris) Effet du groupement cyano sur les propriétés optiques des polymères semi-conducteurs de type poly(p-phénylène vinylène) 16h10 A27. F. Meziane, V. Raimbault, H. Hallil, S. Joly, L. Bechou, D. Rebière, C. Dejous (Univ. Bordeaux) Polymer photonic sensor for integration in a digital microfluidic system

15h50 B26. S.Azzouzi, L. Rotariu, M.Ben Ali, C. Bala (Univ. Bucarest, Univ. Sousse) Amperometric L-lactate biosensor based on gold nanoparticles decorated reduced graphene oxide 16h10 B27. A. Zazoua, N. Khedimallah, A. Sbartai, N. Jaffrezic-Renault (Univ. Jijel, Univ. Lyon) Simultaneous determination of lead, cadmium and Nickel by differential pulse anodic stripping voltammetry at a bare boron-doped diamond microcell electrode functionalized whit tannin from bark of acorn

16h30 : Pause-Café

17h00 - 18h30 Session Posters A

PA1. M. Belhaj, C. Dridi, H. Elhouichet, Y. Leprince-Wang (Univ. Monastir, Univ. Sousse, CNRSM Hammam Lif, Univ. Paris Est) Fabrication and characterization of nanostructured composite films for photovoltaic applications PA2. R. Jemaï, B. Rezgui, K. Zellama, K. Khirouni, S. Alaya (Univ. Gabès, CRTEn, Univ. Picardie) Multiphase silicon carbon film for front contact layer in a Silicon thin film solar cell PA3. A.Azazi, D. Kreher, A. Mabrouk, K. Alimi (Univ. Monastir, ENSTA Palaiseau) Elaboration of P3HT2BTCz for Organic Solar Cells PA4. R. Hamdi, G. Petriashvili ,M. P. De Santo, K. Chubinidze, and R. Barberi (Univ. Tunis, Georgia Tech. Univ., Univ. Calabria) Visual micro-thermometers for nanoparticles photo-thermal conversion PA5. A. Joti, S. Benykrelef, N. Mecirdi and Z. Benamara (Univ. Sidi-bel-Abbès, Univ. Tizi-Ouzou) Improvement of Electrical Parameters of CIGS Photovoltaic Cells By The Modeling and Simulation Using Silvaco Athena-Atlas PA6. M. Mostefaoui, H. Mazari, S. Khelifi, A. Bouraiou, R. Dabou (Univ. Sidi-bel-Abbès) Numerical simulations of InGaN/Si tandem solar cells Using SCAPS-1D PA7. M. A. Benamara, A. Talbi1, B. Akkal, Z. Benamara (Univ. Sidi-bel-Abbès) Ni/SiC–6H Schottky Barrier Diode Interfacial States Characterization Related to Temperature PA8. R. Belroul, Z. Benamara, G. Monier, C. Robert- Goumet et B. Gruzza (Univ. Sid-bel-Abbès, Univ. Clermont) Caractérisation courant-tension et capacité-tension en fonction de la fréquence des nanocomposants à base des matériaux III-V PA9. F. Jabli, H. Mosbahi, M. Gassoumi, C. Gaquiere, M. A. Zaidi, H. Maaref (Univ. Monastir, College of Sciene Zolfi, Univ. Lille) The effect of surface passivation by SiN/SiO2 on electrical characteristics of the Schottky diodes of AlGaN/GaN/Si HEMTs PA10. N. Mecirdi, Z. Benamara, B. Akkal, B. Gruzza, C. Robert-Goumet, L. Bideux (Univ. Sidi-bel-Abbès, Univ. Clermont) Investigation of back to back Schotkky diode in metal/InN/n-InP hetero-junctions PA11. H. MOSBAHI, F.Jabli, M.Charfeddine, M. GASSOUMI, C. GAQUIERE, M. A. ZAIDI, H. MAAREF (Univ. Monastir, Univ. Lille) Current–voltage characteristics of (Mo/Au)/AlGaN/GaN/Si Schottky diodes PA12. I. Najeh, H. Dahman, N. Ben Mansour, L. El Mir (Univ. Gabès,) Electrical Investigations and

Dielectric Properties of Nanoporous Carbon PA13. A. Rabehi, M. Amrani, Z. Benamara, B. Akkal, A. H. Kacha, C. Robert-Goumet, G. Monier and B. Gruzza (Univ. Sidi-bel-Abbès, Univ. Clermont) Simulated Study of current transport in nitride GaAs Schottky diode PA14. N. Mordi, M.Chellali, Z. Benamara, M.Ziane, L.Boutaleb (Univ. Sidi-bel-Abbès) Simulation de la Caractéristique I(V) d’un Transistor HEMT en utilisant Silvaco -Tcad PA15. N. Benseddik, H. Mazari, K. Ameur, Z. Benamara, S. Tizi, A. Hamdoune, M. Mostefaoui, N. Benyahya, R. Khelifi Etude et simulation de la structure Schottky Pt/GaN moyennant le logiciel SILVACO PA16. K. Toumi, and Y. Bourezig (Univ. Sidi-bel-Abbès) ANALYTICAL MODELING OF FIELD EFFECT MOBILITY OF POLYSILICON THIN FILM TRANSISTORS UNDER ILLUMINATION PA17. H. Mazari, R. Khelifi, S. Mansouri, K. Ameur, Z. Benamara, N. Benseddik, S.Tizi, M. Mostefaoui, N. Benyahya, P. Ruterana, I. Monnet, P. Marie, J. M. Bluet (Univ. Sidi-bel-Abbès, INSA Lyon, ENSICAEN) Analysis of capacitance and conductance- frequency characteristics of Au/n-GaN Schottky diode deposited by HVPE PA18. B. Bouabdallah, S. Kheris, Z. Nabi,Y. Bourezig, B. Benichou, N. Benseddik (Univ. Sidi-bel-Abbès) MODELISATION AND OPTIMISATION OF THE OPTICAL GAIN IN NITRIDE QUANTUM WELL LASERS. Study of the temperature effect on the optical characteristics PA19. A. H. Kacha , A. Rabehi, B. Akkal, M. Amrani, Z. Benamara, G. Monier, C. Robert-Goumet and B. Gruzza (Univ. Sidi-bel-Abbès, Univ. Clermont) Effect of the GaN layer on electrical properties in the structures based on GaAs PA20. I. Ghoudi, M. Nouiri, B. Belgacem, Z. Ben Ayadi, S. Alaya (Univ. Gabès, Univ. Tunis, King Faisal University) Investigation of structural and morphological properties of ZnS nanoparticles synthesized by solvothermal route PA21. H. ZERFAOUI, D. DJALEL, .MEBARKIA (Univ. Tébessa) Les Films Minces de Carbonitrure de Silicium SiCN Préparé avec Pulvérisation Cathodique Magnétron et Caractériser Par Spectroscopies UV et IR PA22 A. Ziane, M. Amrani, A. Rabehi (Univ. Sidi-bel-Abbès) Modélisation unidimensionnelle et bidimensionnelle d'une cellule solaire a émetteur sélectif PA23. M. Zemzemi, S. Alaya (Univ. Gabès, King Faisal University) First-principles calculations for surface energy and work function of ZnO and Cu2O PA24. R. Mrad, N. Ben Brahim, N. Bel Haj Mohamed, M. Haouari, R. Ben Chaâbane and H.Ben Ouada (Univ. Monastir) Growth and physical characterization of Cysteine-CdSe nanoparticles PA25. H. Dahman, S. Rabaoui, G. Essalah, A. Alyamani, L. El Mir (Univ. Gabès, KACST, IMSIU, Riyadh) Synthesis of Cu2SnS3 thin �lms by spin coating technique PA26. M. Khadraoui, M.N. Amroune,N. Benramdane, R. Miloua, C. Mathieu, A. Bouzidi, K. Sahraoui (Univ. Sidi-bel-Abbès, Univ. Artois) Optical Constants and Thickness Determination of Bi2S3 and Sn2S3 Thin films using the pattern search optimization Method PA27. S. Bazid, M. El Kolli, A. Medjahed (Univ. Sétif) ETUDE SPECTRALE ET MICROSCOPIQUE DU SYSTÈME GELATINE / CARBOXYMETHYLCELLULOSE EN PRESENCE ET EN ABSENCE DE NaCl, CaCl2 ET DU GLUCOSE PA28. H. Dib, Z. Benamara (Univ. Sidi-bel-Abbès) Effet de la largeur et de la position des joints de grains par rapport à l’interface SiO2/Si-poly sur la capacité C(V) d’une structure MOSP PA29. H. ELHARCHAOUI, H. ELAADAD, T. JERMOUMI, A.CHAHINE (Fac. Sci. Kenitra) Études structurales par Infra-rouge IR des verres à base de phosphate et de fer préparé par la chimie douce PA30. H. ELHARCHAOUI, H. ELAADAD, T. JERMOUMI, A.CHAHINE (Fac. Sci. Kenitra) Elaboration et caractérisation de nouveaux verres borovanadate du système V2O5-B2O3-CaO-Na2O PA31. S. Ghomrasni, S. Ayachi and K. Alimi (Univ. Monastir) New acceptor-donor-acceptor (A-D-A) type copolymers for efficient organic photovoltaic devices PA32. M. HAMICI (Univ. Sétif) Synthesis and characterization of Sno2 – In2O3 thin layers nanostructure PA33. H. Hrichi, K. Hriz, N. Jaballah, R. Ben Chaâbane, H. Ben Ouada, M. Majdoub (Univ. Monastir)

Optical and morphological characterization of New Anthracene-Based Semiconducting Polyethers PA34. A. Langar, N. Sdiri, H. Elhouichet, M. Ferid (CNRSM, Univ. Tunis) Structural, thermal, electrical and dielectrical properties of NaPO3-ZnO-V2O5 PA35. C. Maddi, N. Zehani, T. Tite, A. S. Loir, V. Barnier, K. Wolski, C. Chaix, P. Fortang, J. C. Sanchez-Lopez, T.C. Rojas, N. Jaffrezic- Renault, C. Donnet, F. Garrelie (Univ. Saint-Etienne, Univ. Lyon) Synthesis of CNx films by fs-PLD for electrochemical detection of pollutants PA36. K.Madoui. A.Medjahed, M.Hemissi, M.Bouafia (Univ. Sétif) Effet du Temps de Recuit sur la Morphologie des couches minces de TiO2 PA37. A.Medjahed, M.Bouafia, Y. Bencheikh, K.Madoui, A. Manallah (Univ. Sétif) Caractérisation Qualitative des couches minces de TiO2 par Interférométrie laser PA38. S. Gouadria, H. Dahman, A. Alyamani, K. Omri, L. El Mir (Univ. Gabès, KACST, IMSIU, Riyadh) Negative differential resistance in silicon carbide synthesized by sol-gel route followed by heat treatment PA39. I. Fraj, F.Saidi, L.Bouzaïene, R.Hamila, L.Sfaxi and H.Maaref (Univ. Monastir) Photoluminescence study of InxGa1-xAs multiple quantum wells grown on GaAs high index substrates PA40. H. GAMMOUDI, S. HELALY, R. Chtourou (CRTEn) Optical and morphologic characterization of the pyramid Silicon / porous / APTES / Carbon nanotube structure PA41. Y. Hadj Aissa Fekhar, F. Salah-Belkhodja (Univ. Sidi-bel-Abbès) CONCEPTION OF A MICROWAVES COUPLER USING A COPLANAR STRUCTURE CONTAINING A FERRITE MATERIALS: YIG (Yttrium Iron Garnet) PA42. K. Haj Sadok and M. Haouari (Univ. Monastir) Electrical conduction in vanadium-lithium doped tellurite glasses PA43. R. Lahnayen, M. Ajroud, N. Haj Mohamed, M. Haouari, H. Ben Ouada (Univ. Monastir) Caractérisation structurale et optique des nanoparticules semiconductrices de CdSe - thioglycérol PA44. H. Mazari, A. Boumesjed, K. Ameur, N. Benseddik, Z. Benamara, S. Tizi, A. Hamdoune, M. Mostefaoui, N. Benyahya, R. Khelifi (Univ. Sidi-bel-Abbès, Univ. Tlemcen) Etude et simulation de la structure Schottky Ni/InGaN sous environnement SILVACO PA45. D. MENDIL, S. HASSANI, D.E. GUITOUME, F. YNINEB, B. GUEDOUAR, M. A. DJOUADI and M. KECHOUANE (CDTA, Fac. Phys. Algiers) Effect of Au-Pd catalyst layer and substrate heating conditions on the growth of ZnO nanostructures by thermal evaporation PA46. S. Khelifi, H. Mazari , Z. Benamara, A .Belghachi, L. Boudaoud, and M. Mostefaoui (Univ. Sidi-bel-Abbès) Optimisation et Simulation Numérique d’une cellule solaire à base de ZnTeO PA47. S. Rabaoui, H. Dahman, N. Ben Manssour, L. EL Mir (Univ. Gabès, IMSIU Riyadh) Structural, Morphological and Optical Properties of Cu2SnS3 Nanoparticles Synthesized by Simple Solvothermal Technique PA48. R. Riahi, H. Ezzaouia (CRTEn) Effect of LiBr pore-filling on morphological and optical properties of porous silicon PA49. G. ATTIA, H. HRICHI, R. BEN CHAABANE (Univ. Monastir) Characterization of new anthracene derivatives PA50. Z. Ben Ayadi, H. Mahdhi, K. Djessas, J. L. Gauffier and S. Alaya (Univ. Gabès, Univ. Perpignan, INSA-Toulouse, King Faisal University) The Effect of rf-power on the properties of Ca-doped ZnO thin films sputtered from nanopowders compacted target PA51. Z. Ben Hamed, A. Benchaabane, F. Kouki, M. Abderahmen Sanhoury and H. Bouchriha Effect of Colloidal nanocrystals (NCs) concentration on the basic optical spectra of polymer P3HT film PA52. M. Ben Rabeh and M. Kanzari (ENIT Tunis) Growth and characterization of the new quaternary absorber Cu2FeSnS4 compound for photovoltaic applications PA53. J. Benbelgacem, A. Ibn Marai, M. Nouiri, K. Djessas, Z. Ben Ayadi (Univ. Gabès, Univ. Perpignan) Study of CuInS2 thin films properties obtained by low cost CSVT+D21 method from nanoparticles synthesized by solvo-thermal route PA54. N. Bouazizi, R. Bargougui, A. Oueslati, R. Benslama (Univ. Gabès, Univ. Sfax) Effect of synthesis time on structural, optical and electrical proprieties of CuO nanoparticles synthesized by reflux condensation method PA55. M. Boukhalfa, N. Benramdane, H. Tabet-Derraz (Univ. Sidi-bel-Abbès)

Elaboration and characterisation of Bi2S3: Pb thin films deposited by spray pyrolysis PA56. M. Boulesbaa (Univ. Ouargla) Annealing thermal effect on optical proprieties and bonding chemical characteristics of the SiOxNy:H thin films PA57. I. Chaki, A. Belayachi, T. El Bahraoui, M. Regragui, and M. Abd-Lefdil (Fac. Sci. Rabat) Semiconducting properties of Tm doped Yb-ZnO films by spray pyrolysis PA58. S. Dekhil, H. Dahman, I. Najeh, A. Alyamani and L. El Mir (Univ. Gabès, KACST, IMSIU, Riyadh) Synthesis and Characterization of Iron Pyrite FeS2 Nanoparticles by Solvothermal and Hydrothermal Techniques PA59. R. Dhahri, M. Hjiri, L. El Mir, A. Bonavita, S. G. Leonardi, G. Neri (Univ. Gabès, IMSIU, Riyadh, Univ. Messina) Study on Al-doped ZnO gas sensors enhanced by UV light under variation of temperature and test gas concentration PA60. W. Djeridi, A. Ouederni, P. L.Llewellyn and L. El Mir (Univ. Gabès, Univ. Aix-Marseille, IMSIU, Riyadh) Effect of pyrolysis temperature on structure and CO2 adsorption properties of microporous carbon material PA61. M. Kraini, N. Bouguila, C. Vázquez-Vázquez, M. A. López-Quintela, S. Alaya (Univ. Gabès, Univ. Santiago de Compostela) Structural, morphological and optical properties of In2S3:Sn thin films obtained by spray technique PA62. R. Mendil, Z. Ben Ayadi, M. Said, E. Hernandez, K. Djessas (Univ. Gabès, Univ. Perpignan, Univ. Djibouti) Growth of ZnS nanoparticles synthesized by Solvo-thermal route PA63. J.Chermiti, S.Azzouzi, M.Ben Ali, M.Trabelsi, A.Errachid, N. Jaffrezic-Renault (Univ. Sousse, IPEST, Univ. Lyon) Modeling and Analysis of Low Frequency Noise in Ion-Field-Effect Transistors sensors PA64. S. Kortli, M. Ben Ali, Ch. Ben Salah, C. Dridi, A. Errachid (Univ. Sousse, IPEST, Univ. Lyon) Conception des systèmes électroniques dédiés aux microélectrodes en vue de réalisation de réseau de capteurs pour la détection des métaux lourds PA65. A. Mami, N. Bennaji, I. Mellouki and N. Yacoubi (IPEIN Nabeul) Detection of defects of piezoelectric sensor by a microcontroller PIC16F877A PA66. M. Erouel, M. Iazykov, M. Phaner-Goutorbe and K. Khirouni (Univ. Gabès, INSA Lyon, EC Lyon) Fluorinated parylene: material properties and application as low dielectric constant polymer gate dielectric for organic transistors PA67. I. OUAHAB and R.NAOUM (Univ. Sidi-bel-Abbès) Silicon-Polystyrene Hybrid Nonlinear Photonic Crystals For Ultralow Power All Optical Switch PA68. S. NASRAOUI, A. TOUHAMI, R. BEN CHAABANE (Univ. Monastir) Theoretical analysis of anthracene and its derivatives using DFT and TD-DFT PA69. M. Sahraoui, A. Abderrahmen, Z. Baatout, N. Jaballah, H. Ben Ouada, A. Gharbi (Univ. Monastir, Univ. Tunis) Alignement des cristaux liquides nématiques en utilisant la �-cyclodextrine native et modifiée PA70. H. Souissi, L. Mejrissi, B. Oujia and F. X. Gadéa (Univ. Monastir, King Abdulaziz University, Univ. Toulouse) Theoretical ab initio investigation of the ground state X1�+ of the Silver hydride AgH PA71. A. Touhami, R. Ben Chaabane, A.R. Allouche, K. Hriz, H. Ben Ouada, M. Majdoub (Univ. Monastir, Univ. Lyon) DFT study of the effect of substituents on the absorption, emission, and electrical properties of anthracene derivatives PA72. R. Zgueb, H. Dhaouadi (Univ. Tunis) Etude diélectrique d’un cristal liquide smectique chiral PA73. N. Ben Brahim, N. Bel Haj Mohamed, M. Haouari, R. Ben Chaâbane and H.Ben Ouada (Univ. Monastir) Time resolved and temperature dependence of the radiative properties of thioglycerol capped CdSe nanoparticles PA74. H.Tabet et R. Doufnoune (Univ. Sétif) Elaboration et Caractérisation d'un Matériau Hybride Organique -Inorganique : Influence de l'Interface sur les Performances des Composites à Matrice Thermoplastique PA75. M.D.Dankoco, E. Bénevent, E. Bergeret, L. Gallais, M. Bendahan (Aix-Marseille Univ.) Etude et réalisation de capteurs de température sur support souple PA76. S. Ghomrasni, I. Aribi, S. Ayachi, A. Haj Said and K. Alimi (Univ. Monastir, Univ. Tunis) Molecular structure - optical property relationships of 1, 3-bis (4-methoxyphenyl) prop-2-en-1-one: A DFT and TD-DFT Investigation PA77. H..GHRIEB, N.Kahla, M.Boumedjout, L.Kaboub, A.Gouasmia (Univ. Tebessa, Univ. Sétif)

ELABORATION ET CARACTERISATION D’UN NOUVEAU MATERIAU SEMI-CONDUCTEUR A BASE DE TETRATHIAPENTALENE PA78. H. Dib, A. Gasmi, R. Naoum, S. Bouamami, Z. Kari (Univ. Sidi-bel-Abbès) Optimisation d’un filtre add-drop pour l’extraction d’une longueur d’onde dans la bande utilisée pour les télécommunications optiques PA79. R. Eloualhazi, H. Berriche (Univ. Monastir, King Khalid University) A theoretical investigation of the low-lying 1�+ states of the MgNa+ cationic molecule PA80. O. Hadj Rahmoun, C. Bouasla, N. Derguini, M.T. Belaroussi, M. Saïghi, N. Tayebi (CDTA, Fac. Phys.Algiers, Stanford Univ.) Study of a liquid mixture in a passive floor-grooved micromixer PA81. A. Nakhli, M. Bergaoui, M. Khalfaoui, J. Möllmer, A. Möller, A. Ben Lamine (Univ. Monatir, Institut für Nichtklassische Chemie Leipzig) Monolayer model for interpreting the gas adsorption onto metal organic frameworks at high pressure PA82. N. Ben Mansour, I. Najeh , S. Mansouri and L. El Mir (Univ. Gabès, IMSIU Riyadh) Effect of pyrolysis temperature on the properties of an organic-inorganic nanocomposite based on pyrogallol and formaldehyde PA83. B.Berrahal, Z.Mahdjoub (Univ. Sidi-bel-Abbès) Stabilité De La Température D’un Laser Système Pour Les Télécommunications Optique PA84. M. KHAMMAR (Univ. Sétif) Nanohole thin gold film as plasmonic biosensor PA85. D.E. GUITOUME, D. MENDIL, F. YNINEB , M.S. AIDA, N. ATTAF (Univ. Constantine) ZnO nanorods growth by free template sol-gel technique PA86. K. Hamouda, A.P. Babichev (Univ. Bab Azzouar, Don State tech. Univ.) Process for Treatment Surface by Using Granular vibro-impact PA87. Z. Kari, H.Dib, N. Doumit, H.Shall, M.Kadi, J.J. Rousseau (Univ. Sidi-bel-Abbès, Univ. Saint-Etienne L’effet de la deuxième couche du YIG sur le rayonnement électromagnétique d’une inductance intégrée PA88. N.Khadir, A.Belasri (Univ. Oran) Production d’hydrogène par plasma froid riche en hydrocarbure, application aux piles d’hydrogène PA89. Y.Yahia Lahssene, M. Keche, M. Safer (Univ. Oran) Détection de l'hypovigilance chez le conducteur par vision PA90. S. Mnefgui, N. Zaidi, A. Dhahri, E.K. Hlil, J. Dhahri (Univ. Monastir, Univ. Grenoble) Behavior of the magnetocaloric effect and critical exponents in La0.67Sr0.33Mn1-xVxO3 manganite oxide PA91... A. Nakhli, M. Bergaoui, M. Khalfaoui, J. Möllmer, A. Möller, A. Ben Lamine (Univ. Monatir, Institut für Nichtklassische Chemie Leipzig) Energetic study of gases molecules onto HKUST-1 using the statistical physics PA92. S. Bouamami, R. Naoum (Univ. Sidi-bel-Abbès) New version of seven wavelengths demultiplexer based on the microcavities in a two-dimensional photonic crystal PA93. R. Naoum, S. Bouamami (Univ. Sidi-bel-Abbès) Temperature effect on the tenability of an eight-channel demultiplexer PA94. S. Saidi, H. Loukil et A. Belasri (Univ. Oran) MODELISATION BIDIMENTIONNELE D’UNE DECHARGE A BARRIERES DIELECTRIQUE D’UNE LAMPE POUR UN MELANGE NEON-XENON PA95. M. Selmi, F. Echouchene, H. Barhoumi, H. Belmabrouk (Univ. Monastir) Enhancement of microfluidic immunoassay chips efficiency by means of fluid flow engineering PA96. F. Palacio, J. D. Prades, M. Martínez, M. Lopez, J. M. Gómez and A. Errachid (Univ. Barcelona, Univ. Lyon) Portable Instrumentation for Impedance Measurements in Biomedicine based on FFT. The Interleukin-10 protein detection case study PA97. F.GHALEB and A.BELASRI (Univ. Oran) Townsend Electrical Discharge for Gases PA98. L. Guerandi, A. Errachid,N. Jaffrezic Renault (Univ. Oran, Univ. Lyon) Biomedical pH-ISFET based urea biosensor and CMOS Readout Circuity PA99. L. Guerandi, M. Ben Ali, A. Errachid,N. Jaffrezic Renault (Univ. Oran, IPEST, Univ. Lyon) Computer Aided Design and Circuitry CMOS Readout Reponse Based capacitance-biosensors measurement for formaldehyde and methylamine detection PA100. N. Ben Mansour, C. Dridi, N. Yaakoubi, L. Fakri-Bouchet (Univ. Sousse, Univ. du Maine, INSA-Lyon) Implantable NMR microcoil: Design, Numerical Simulation and Fabrication PA101. S. Kheris, B. Bouabdallah, Z. Nabi, N. Benseddik (Univ. Sidi-bel-Abbès)

ETUDE DE LA COMPENSATION DES PHENOMENES D’ATTENUATION ET DE DISPERSION CHROMATIQUE DANS UNE LIAISON PAR FIBRE OPTIQUE LONGUE DISTANCE PA102. M. Dekmous, H. Mazari (Univ. Oran, Univ. Sidi-bel-Abbès) Réalisation d’un CARDIOPHONE ou stéthoscope électronique moyennant un capteur piézoélectrique PA103. L. Guedri-Knani, M. Khelifa, C. Dridi, N. Yaakoubi (Univ. Monastir, Univ. Sousse, Univ. Du Maine) Enhancement of optical and surface properties of treated flexible materials for implantable Microsystems development PA104. H. Loukil, K. Khodja, S. Saidi et A. Belasri (Univ. Oran) Study of DBD xenon excimer UV light source properties with different driving waveforms PA105. F.S.NOUAR, S.MANSOURI, M.AMRANI and P.Marie (Univ. Sidi-bel-Abbès, ENSICAEN) THREE-DIMENSIONAL SEMICONDUCTOR DEVICES TRANSPORT SIMULATION LIFETIME AND RELAXATION PA106. I. Saidi , S. Saadaoui, H. Mejri, H. Maaref (Univ. Monastir) Theoretical study of the kink effect in AlGaN/GaN/SiC High Electron Mobility Transistors PA107. A. Mhamdi, M. Amlouk and S. Belgacem (Univ. Monastir) Study of copper doping effects on structural, optical and electrical properties of sprayed ZnO thin films PA108. M. Chemingui, T. Soltani, T. Othman (FS Tunis) Etude diélectrique et électro-optique des mélanges de deux énantiomères d'un cristal liquide ferroélectrique PA109. A. Arfaoui, B. Ouni, S. Touihri, T. Mannoubi (Univ. Tunis El Manar) Investigation into the optoelectrical properties of tungsten oxide thin films annealed in an oxygen air PA110. S. Rajeh, A. Mhamdi, K. Khirouni, M. Amlouk and S. Guermazi (IPEI Sfax, Univ. Tunis El Manar, Univ. Gabès) Structural and optical properties of Ni doped ZnO thin films prepared by spray pyrolysis technique PA111. A. Arfaoui and T. Mannoubi (Univ. Tunis El Manar) Structural, optical and electrical studies on MoO3-x thin films annealed in different oxygen environment PA112. A. Jdidi, S. Abdi-Ben Nassrallah, M. Saïd, J.-L. Lazzari (Univ. Monastir, Aix-Marseille Univ.) Theoretical study of AlzGa1-x-zInxAsy Sb1-y/GaSb based quantum well achieving mid-infrared emission PA113. H. Tayoub, B. Zebentout, A. Bensmain, Z. Benamara, N.Elghoul, R. Djemai, K. Khirouni and T. MOHAMMED-BRAHIM (Univ. Sidi-bel-Abbès, Univ. Gabès, Univ. Rennes) 2D-Numerical Simulation of μc-Si:H TFT’s PA114 . K. Ameur, H. Mazari, Z. Benamara, N. Benseddik, R. Khelifi, M. Mostefaoui, N. Benyahya, C. Robert-Goumet (Univ. Sidi-bel-Abbes, Univ. Clermont) Analysis of current-voltage and capacitance-voltage characteristics in Schottky barrier diodes based on nitrided GaAs(100) PA115. N. Bennaji, A. Mami, M. Khaled and N. Yacoubi (IPEIN Nabeul) Detection of defects of piezoelectric sensor with a microcontroller PIC16F877 PA116. M. Ben Amor, K. Boubaker, M. Amlouk (Univ. Tunis El Manar) Structural, optical and electrical studies on Mg-doped NiO thin films for sensitivity applications PA117. H. Belaid, M. Nouiri, Z. Ben Ayadi, K. Djessas, L. El Mir (univ. Gabès, Univ. Perpignan, IMSIU Riyadh) Substrate type effect on the electrical behavior of ZnO:In/PS/Si(n/p) solar cell structures PA118. N. Bouziane, S. Tizi, B. Zebentout, R. Djemai, N. El Ghoul, Z. Benamara and K. Khirouni (Univ. Sidi-bel-Abbès, Univ. Gabès) Electrical characterization of PN junction based on thin silicon layers for photovoltaic applications PA119. R. Alaya, M. Mbarki, A. Rebey (Univ. Monastir, Univ. Gabès) Ab initio study of pressure-induced phase transitions of GaN1-xBix alloys PA120. A. Bazine, A. Azzouz, L. Guedri-Knani, C. Dridi, N. Yaakoubi, P. Picart (Univ. Monastir, Univ. Sousse, Univ. du Maine) Fourier Digital Holography investigations on treated Polymer surfaces PA121. H. Faltakh, R. Bourguiga, S. Ben Dkhil, J. Davenas (Univ. Bizerte, Univ. Aix-Marseille, Univ. Lyon) Extraction of different parameters of hybrid solar cell based on PVK/ silicon nanowires

20h30 - 21h30 Réunion-Débat “Femmes et Sciences”

Prof. Martine LUMBRERAS

Jeudi 6 Novembre 2012

8h30 Conférence plénière IV

Arben MERKOCI, ICREA & Catalan Institute of Nanoscience and Nanotechnology NANOMATERIALS-BASED PLATFORMS FOR BIOSENSING APPLICATIONS

9h00 Conférence plénière V

Sergio BIETTI (Università di Milano-Bicocca, Italia) Droplet Epitaxy and applications

9h30 Conférence plénière VI

AISSAT Abdelkader: University of Blida (Algeria) Modélisation et simulation d’une structure à base de GaAsNBi pour le photovoltaïque

10h00 Pause-Café

Session A3 : Nouveaux Matériaux :

Composants Electroniques

10h30 A31. Conférence-clé S. MIRABELLA CNR-IMM MATIS and Univ. Catania Dip. Fisica e Astronomia, Catania, Italy Semiconductor nanostructures: from photovoltaics to biosensing applications

11h00 A32. N. Benyahya, H. Mazari, N. Benseddik, K. Ameur, Z. Benamara, M. Mostefaoui, R. Khelifi, J. M. Bluet (Univ. Sidi-bel-Abbès, INSA Lyon) Electrical characterization and simulation of the InAlN HEMTs

11h20 A33. A. Douara, B. Djelouli, H. Abid, A. Rabehi, A.Ziane (Univ. Sidi-bel-Abbès, Univ. Saida) Simulations current and capacity models of transistors AlGaN/GaN HEMTs

Session B3 : Biosystèmes I

10h30 B31. Conférence-clé S. RIFFARD (Univ. Saint-Etienne) Legionella: how to detect the bacterium in its environmental niches?

11h00 B32. D. SBOUI, M. SOUIRI, M. BEN ISMAIL, T. EPALLE, R. MZOUGHI, F; GIRARDOT, S. ALLEGRA, N. JAFFREZIC, S. RIFFARD, A. OTHMANE (Univ. Monastir, Univ. Lyon, CHU Sousse) Development of an electrochemical immunosensor for the detection of Legionella pneumophila VBNC forms in environmental samples 11h20 B33. L. RENAUD, D. SELLOUM, S. TINGRY (Univ. Lyon, Univ. Montpellier, Univ. Sétif) Low-cost 3D Glucose/02 microfluidic biofuel cell

11h40 A34.B. Ben Abdellaziz, N. Ismail, A. Kalboussi (Univ. Monastir) Caractérisation électrique et simulation des transistors organiques

12h00 A35. A. Talbi, M. A. Benamara, Z. Benamara, B. Akkal, B. Gruzza, C. Robert, L. Bideux, G. Monier (Univ. Sidi-bel-Abbès, Univ. Clermont) Study of InP(100) nitridation using XPS spectroscopy and electrical analysis: Effect of time deposition of the InN thin layers

12h20 A36. L. Fradetal, E. Bano, G. Attolini and V. Stambouli (INP Grenoble, IMEM Parma) Silicon Carbide Nanowire Field Effect Transistor for electrical label-free DNA detection

11h40 B34. P. Namour, L. Jobin, N. Jaffrezic (Univ Lyon, IRSTEA Lyon) Activité électrochimique sédimentaire et son utilisation dans l’épuration des eaux usées

12h00 B35. A. Mars, C. Parolo, W. Argoubi, M. Saadaoui, C. Mayorga, A. de la Escosura, A. Merkoçi and N. Raouafi (Univ. Tunis, UA Barcelona) Ferrocene-functionalized gold nanoparticles as versatile transducing system for the design of new biosensing platforms

12h20 B36. O. M. Ba, A. Ponche, P. Marmey, T. Jouenne, O. Gallet, K. Anselme and A. C. Duncan (Univ. Rouen, IS2M Mulhouse) Etude physico -chimique surfacique à long -terme d’un polystyrène polystyrène post-traitement plasma froid : pertinence d’une période d’instabilité critique

12h40 Repas

Session A4 : Nouveaux matériaux : ZnO et GaAs-Bi-N

14h00 A41. S.BENYKRELEF , A.JOTI, Z.BENAMARA (Univ. Sidi-bel-Abbès) Etude et Simulation des phénomènes de transport dans les dispositifs réalisés à partir de matériaux III-V nitrurés

14h20 A42. M.Belhaj, C. Dridi, H. Elhouichet, J.C Valmalette (Univ. Monastir, Univ. Sousse, CNRSM Hammam Lif, Univ. Sud Toulon Var) Structural and optical properties of poly (N-vinyl carbazole) and ZnO nanoparticles based composites

14h40 A43. K.M.A. Boureguig , H. Tabet-Derraz, A. Bouzidi, N. Benramdane (Univ. Sidi-bel-Abbès) Study of Optical Behavior of Compound Semiconductors (ZnO/Co3O4) in Thin Layers Obtained by Spray Pyrolysis Technique

15h00 A44. A. Elfakir, A. Belayachi, and M. Abd-Lefdil (Fac. Sci. Rabat) Effect of the Nd and Tm co-doping on the

Session B4 : Capteurs chimiques I

14h00 B41 S.Azzouzi, M.Ben Ali, N.M.Nooredeen, M.N.Abbas, C.Dridi, A.Errachid (Univ. Sousse, IPEST, N. R. C., Cairo, Univ. Lyon)Citrate Bio-Sensors based on Iron (II) phthalocyanine acrylate polymer derivate using impedance spectroscopy and potentiometric measurements

14h20 B42. Mohammed Nooredeen Abbas (NRC Cairo) Metal Phthalocyanines in Bio/Chemical Sensors

14h40 B43. I. Zahou, S. Touaiti, R. Mlika, R. Ben Chabaane, B. Jamoussi, H. Ben Ouada (Univ. Monastir) Electrochemical behavior of quinoleinoxy- substituted Zinc phtalocyanine for the detection of Bisphenol A 15h00 B44. A. Sbartai, A. Chrouda, P. Namour, N. Jaffrezic-Renault (Univ. Lyon, IRSTEA Lyon)

structural, optical and electrical properties of ZnO thin films prepared by spray pyrolysis

15h20 A45. R. Hamila, F. Saidi, H. Maaref, P. Rodriguez , Laurent Auvray (Univ. Monastir, Univ. Kairouan, Univ. Lyon) Radiative B-localized recombination and confinement in BInGaAs/GaAs quantum well structures

15h40 A46. F.Belkhiria, F.I.H.Rhouma, R.Chtourou (Research and Technology Center of Energy, Borj-Cedria) Synthesis and characterization of High qualities graphene nanosheets via electrochemical exfoliation of graphite flakes

Conception et développement de nouveaux microcapteurs chimiques pour la détection des métaux dans les eaux

15h20 B45. S. Chatti, A. Fildier, A. Bonhommé, C. Sanglar, P. Marote, O. Boyron, H. Casabianca (Univ. Lyon) Elaboration de nouveaux matériaux dérivés du polydiméthylsiloxane (PDMS) utilisés comme barreaux d’agitation (SBSE) pour l’extraction de composés d’intérêt dans des matrices complexes

15h40 B46. D. ACH, S. BRIANCON, G. BROZE, Y. CHEVALIER (Univ. Lyon) MICROENCAPSULATION PAR COACERVATION COMPLEXE DES PROTEINES DU LACTOSERUM ET DE LA GOMME D’ACACIA

16h00 : Pause-Café

16h30 - 18h30

Session Posters B

PB1. N. Rokhaya Faye, M. Mathelié�Guinlet, F. Moroté, I. Gammoudi, C. Grauby�Heywang, T. Cohen�Bouhacina (Univ. Bordeaux) Study by AFM and fluorescence microscopy of the interaction of silica nanoparticles with planar lipid monolayers and bilayers used as simplified models of cellular membranes PB2. A. Rouis, R. Mlika, U. Darbost, I. Bonnamour, H. Ben Ouada (Univ. Monastir) Spectrophotometric and voltammetric characterization of sensing films based on a novel calix[4]dicyano-diimidazole for the detection of copper (II) PB3. W. Ben Mefteh, H. Touzi, Y. Chevalier , R. Kalfat, N. Jaffrezic-Renault (Univ. Lyon, Univ. Monastir, INRAP Sidi Thabet) Functionalization of gold surface with terpyridine ligands by means of cysteamine and mercaptopropionic acid self-assembled monolayers and the utilization as a Gadolinium sensor in urine PB4. A.Chrouda, A.Sbartai, F. Bessueille, A. Maaref, and N. Jaffrezic-Renault (Univ. Monastir, Univ. Lyon) Electrically addressable diazonium-functionalized antibodies on BDD microcell for detection of Ochratoxin A PB5. A. GAIED, N. JABALLAH, M. BRAIEK, N. JAFFREZIC-RENAULT, M. MAJDOUB (Univ. Monastir, Univ. Lyon) ELABORATION D’UN NOUVEAU CAPTEUR DE DOPAMINE EN PRESENCE D’ACIDE ASCORBIQUE PB6. Y. Braham, H. Barhoumi, A. Maaref, A. Bakhrouf , C. Grauby Heywang, F. Moroté, T. Cohen Bouhacina, N. Jaffrezic-Renault (Univ. Monastir, Univ. Bordeaux, Univ. Lyon) Characterization of iron oxide nanoparticles in interaction with Proteus mirabilis bacteria for urea biosensor application PB7. C. Ben Ali Hassine, H. Barhoumi, A. Maaref and N. Jaffrezic (Univ. Monastir, Univ. Lyon) Electrochemical study of modified carbon electrode by aurintricarboxylic acid ammonium salt (ATA) for heavy metal ions detection PB8. F. Boussema, Y. Ghandour, H. Barhoumi, B. Mohamed Salah, A. Maaref (Univ. Monastir) Electrochemical nitrite sensor based on tetrabutylammonium microcrystalline salts of lacunary �-Keggin-

polyoxophosphomolybdate PB9. F. Maâtouk, A. Ben Esseghaier, H. Barhoumi, M. Askri, A. Maaref and N. Jaffrezic (Univ. Monastir, Univ. Lyon) Characterization of New Organic Derivatives azadiene for Electrochemical Copper sensors development PB10. A.Touati, M. Benounis, R. Kherrat, S. Zouggar (Univ. Khenchela, Univ. Annaba) NOUVEAU CAPTEUR A ION SELECTIF A BASE DE ZEOLITE POUR LA DETECTION DU ZINC PB11. R. Beji, H. Barhoumi, A. Maaref, N. Jaffrezic-Renault (Univ. Monastir, Univ. Lyon) Electropolymerized Polyaniline- Eriochrome Black T Nanocomposites on Platinum Electrode for HRP enzyme immobilization and H2O2 sensor development PB12. Y. Ghadhab Trabelsi, H. Barhoumi, Y. Braham, H. Majdoub and A. Maaref (Univ. Monastir) Alginate Polysaccharide Modified Glassy Carbon Electrode for ion-sensitive sensor development PB13. A. Ben Esseghaier, F. Maâtouk, H. Barhoumi, M. Askri, A. Khatyr, K. Monnier-Jobé, M. Knorr (Univ. Monastir, Univ. Franche-Comté) Synthesis and characterization of New Organic azadiene derivatives for ion sensors application PB14. K. Zinoubi , S. Bourigua , H. Barhoumi , A. Maaref (Univ. Monastir) Detection of Trace Heavy Metal ions by Anodic Stripping Voltammetry using Gold Nanoparticles and L-cysteine PB15. K.Abderrahim , S.Abderrahmane , S.Ouchenane et Jean-Pierre Millet (Univ. Annaba, INSA Lyon) Effet inhibiteur d'un éthanolamine sur la corrosion de l'acier XC 38 PB16. K.Abderrahim , S.Abderrahmane , S.Ouchenane et Jean-Pierre Millet (Univ. Annaba, INSA Lyon) Mécanisme d’inhibition de la corrosion du Cuivre par le miel naturel PB17. A. Abidli, S. Hamoudi, K. Belkacemi (Centre de Recherche en Chimie Verte et Catalyse, Québec) Synthesis, characterization and potential metathesis activity of MTO catalyst supported on well-defined hexagonal mesoporous alumina material PB18. K.Abderrahim, S.Abderrahmane, Jean-Pierre Millet (Univ. Annaba, INSA Lyon) Etude électrochimique du cuivre vis-à-vis de la corrosion en milieu salin aqueux en absence et en présence d’inhibiteur PB19. Z. BAATOUT, S. TEKA, N. JABALLAH, N. SAKLY, M. MAJDOUB (Univ. Monastir) Water-insoluble benzylated �-cyclodextrin derivatives for humidity sensors PB20. R. Bargougui, J.F. Hochepied, M.H. Berger, S.Ammar (ENI Sfax, Mines Paris Tech, ENSTA, Univ. Gabès) Role of polyol in the Synthesis of TiO2 ,SnO2 and Ti0,5Sn0,5O2 using microwave heating technique Synthesis and characterization of New Organic azadiene derivatives for ion sensors application PB21. N. Ben Messaoud, M. Braik, C. Dridi, M. Ben Ali, M. Ali, M. Abbes, N. Jaffrezic Renault, A. Errachid (Univ. Monastir, Univ. Sousse, NRC Cairo, Univ. Lyon)A new CoPc ionophore based thin films: Fabrication, characterization and perchlorate sensor application PB22. R. Khammar, A. Bendjeddou, T. Abbaz, A. Gouasmia, M. Dekhici and D. Villemin (Univ. Souk Ahras, Univ. Tebessa, Univ. Caen) SYNTHESIS AND ELECTROCHEMICAL BEHAVIOUR OF NEW BIS [BENZENE-FUSED BIS(TETRATHIAFULVALENE)] AND ELECTRICAL CONDUCTIVITY OF THEIR ORGANIC MATERIALS PB23. S. BENGHANEM, M. ELKOLLI MERBEH (Univ. Sétif) MODIFICATION CHIMIQUE D’UN MATERIAUX D’ORIGINE NATUREL POUR OBTENIR UN NOUVEAU MATERIAU PB24. L.Benammar, M. Benounis (Univ. Khenchela) Nouveaux biocapteurs pour le contrôle des phosphates dans les eaux usées de la région de Khenchela : Elimination biologique des phosphates des eaux usées par culture mixte PB25. A. Khedouma, M. Benounis (Univ. Khenchela) DENITRIFICATION BIOLOGIQUE DES EAUX USEES DE LA REGION DE KHENCHELA PB26. Z. BEN REJEB, A. ABIDLI, S. HAMOUDI, K. BELKACEMI (UNIV. LAVAL) Silica-based biomaterials, a new approach for �-Galactosidase immobilization towards galacto-oligosaccharides biosynthesis

PB27. H. Bey, A. Aschi (Univ. El Manar Tunis) Effets de la dénaturation chimique sur les changements conformationels d’une enzyme PB28. S. Bizid, R. Mlika, A. Haj Said, M. Chemli, H. Ben Ouada, H. Korri Youssoufi (Univ. Monastir, Univ. Paris-Sud) Etude des propriétés de transfert de charge dans un polymère conducteur redox (polyphényle-ferrocene) et application dans les biocapteurs électrochimiques d’ADN PB29. C. BOUASLA, N. TAYEBI, O. HADJ RAHMOUN, N. Derguni (CDTA Algiers, Univ. Stanford) DNA Hybridization Sensors: Study of The electric double layer capacitance based on the modified Poisson-

Boltzmann model for nanogap electrodes PB30. M.Boumedjout, H.Douib, S.Tiaouinine, L.Kaboub, A.K.Gouasmia (Univ. Tébessa) PREPARATION OF NEW ORGANIC CONDUCTOR BASED ON TETRATHIAPENTALENE PB31. A.Bourezgui, I. Kacem, M. Karyaoui and R. Chtourou (CRTEn) A simple method for sol-gel synthesis of porous TiO2 thin films template by polystyrene (PS) latex spheres morphological, optical and photocatalytic study PB32. W. Bousslama, H. Elhouichet, M. Férid (CNRSM Hammam Lif, Univ. El Manar Tunis) Effect of Fe doping on structural and photocatalytic properties of ZnO PB33. K. BOUZID, N. E. BELIARDOUH, C. NOUVEAU (Univ. Annaba, Arts et Métiers-Paris Tech) COMPORTEMENT A LA CORROSION ET A L’USURE DE DEPOTS EN COUCHES MINCES CrN ET CrXN (X=Mo, Zr, V) ELABORES PAR PULVERISATION CATHODIQUE MAGNETRON RF. PB34. S. Chaoui, D. Smail, M. Berabou, D. Benachour (Univ. Sétif) Etude thermique d’un bio-nanocomposite PLA/Amidon PB35. N. B. CHELLAOUI, M. MAMI, R. DORBEZ-SRIDI et A. El ABED (Univ. Monastir, ENS Cachan) Synthèse de microbilles de verres bioactif pour la délivrance de principe actifs par voie sol-gel PB36. M. A. DJEBBI, M. MEKNI, M. SADIKI, K. CHARRADI, S. ELABED, N. JAFFREZIC, P. NAMOUR, A. BEN HAJ AMARA (Univ. Bizerte, CNGMO Tunis, Fac. Sci. Fèz-Saïs, Univ. Lyon) Preparation of layered double hydroxide nanocomposites using berberine chloride and their anti-bacterial activity PB37. W. Djeridi, N. Ben Mansour, A. Ouederni, and L. El Mir (Univ. Gabès, IMSIU, Riyadh) Preparation and characterisation of electrical conducting nanoporous carbon structures derived from olives stones PB38. F. Dridi, M. Marrackchi, M. Gargouri, S. Dzyadevych, F. Vocanson, J. Saulnier, N. Jaffrezic-Renault, F. Lagarde (Univ. Lyon, INSAT Tunis, NAS Ukraine) Caractérisation électrochimique des propriétés conductrices d’hybrides nanoparticules d’or/polyéthylèneimine/alcool polyvinylique/thermolysine. Application au développement d’un biocapteur enzymatique PB39.�M. Braik, C.Dridi, M. Ben Ali, M. Ali, M. Abbes, N. Jaffrezic Renault, A. Errachid (Univ. Monastir, Univ. Sousse, NRC Cairo, Univ. Lyon) Study of optical, morphological and electrical properties of new cobalt phthalocyanine derivatives PB40. O. M. Ba, A. Ponche, O. Gallet, P. Marmey, K. Anselme, A.C. Duncan (Univ. Rouen, IS2M Mulhouse) Surface immobilization of a green fibronectin-like protein onto cold plasma modified polystyrene substrates PB41. H. EL AADAD, H. ELHARCHAOUI, T. JERMOUMI, A. CHAHINE (Fac. Sci. Kenitra) Étude Préliminaire De L’effet Catalytique Des Films Minces En Polystyrène Elaborés Par Voie De Chimie Douce PB42. H. EL AADAD, H. ELHARCHAOUI, T. JERMOUMI, A. CHAHINE (Fac. Sci. Kenitra) Elaboration Et Caractérisation Structurale Et Thermique Des Films Minces A Base De Polystyrène / Triméthylphosphate Elaborés Par Voie De Chimie Douce PB43. A. GAIED, N. JABALLAH, M. MAJDOUB (Univ. Monastir) CAPTEURS ELECTROCHIMIQUES DE DOPAMINE A BASE D’AMINO-�-CYCLODEXTRINE PB44. H. GAMMOUDI, S. HELALY, R. Chtourou (CRTEn) Caractérisation optique et morphologique de la structure Silicium pyramidale poreux / APTES / Nanotube de Carbone pour application Photocatalyse PB45. I. Gammoudi, A. Soussou, V. Raimbault, F. Moroté, C. Grauby�Heywang , D. Rebière, R. Kalfat, A. Othmane, C. Dejous, T. Cohen�Bouhacina (Univ. Bordeaux, INRAP, Univ. Monastir) Control and validation of physicochemical parameters optimized for multilayered polyelectrolyte film deposition by AFM and Love wave, QCM�D and electrochemical sensor PB46. T. Tite, A.-S. Loir, C. Donnet, S. Reynaud, J. -Y. Michalon, F. Vocanson, V. Barnier and F. Garrelie (Univ. Saint-Etienne) 3D Graphene architecture grown by pulsed laser deposition as a robust SERS platform for pesticides detection PB47. A.Gharbi, A.Himour, S.Abderrahmane, K.Abderrahim et K.Maddouri (Univ. Annaba) Effet Inhibiteur du 2,2-bipyridyl sur la corrosion de l’acier inoxydable austénitique AISI309 dans 0,5M H2SO4 PB48. W. Gtari, H. Bey, A. Aschi et O. Tahar (Univ. Tunis El Manar) Caractéristiques d'un polysaccharide dans un mélange d'eau/alcool PB49. G. El Khamssa, O..Hamdaoui (Univ. Annaba) Biosorption kinetics and thermodynamics of basic blue 9 onto cattail leaves from aqueous media PB50. A. Godain, M. Erouel, T. Vogel et N. HADDOUR (EC Lyon, Univ. Gabès) Un nouveau système microfluidique en configuration pile à combustible microbienne pour étudier les performances électrocatalytiques des biofilms bactériens

PB51. S. HALLADJA, H. AYADI, T. MEKHALIF, Z. BOUCERIB (Univ. Skikda) Adsorption of BSA on the poly (acrylamide co acrylic acid) complexed with copper ion PB52. H. HRICHI, L. MONSER, N. ADHOUM (INSAT) Gliclazide voltammetric sensor based on electropolymerized molecularly imprinted polypyrrole film onto glassy carbon electrode PB53. I. Saifi, T. Douadi (Univ. Sétif) Synthèse, application d’un nouveau composé comme inhibiteur de corrosion du cuivre en milieu acidePB54. I. JEBALI et J.E. BELGAIED (INSAT) Fabrication et caractérisation d'un nouveau capteur potentiométrique sélectif au losartan potassique, application au dosage dans des formulations pharmaceutiques PB55. R.. Kerkour, S. Chafaa (Univ. Sétif) SYNTHÈSE ET CARACTÉRISATION SPECTROSCOPIQUE ET ÉLECTROCHIMIQUE D’UN ACIDE MONOPHOSPHONIQUE PB56. A.KOUACHE, H.DEHDOUH, B.IDIR, A.ZIOUCHE, H.HAMITOUCHE (CSC Cheraga) Etude microstructurale et électrochimique d’un acier au carbone traité thermiquement PB57. S. KOURAS, R. MAHAMDI (Univ. Ouargla, Univ. Batna, Univ. Constantine) Etude et identification paramétrique d’un capteur chimique organique PB58. A.V. Mamykin, A.L. Kukla, A.S. Maistrenko, Yu.V. Ushenin (NAS Ukraine) IMPEDIMETRY BASED DIAGNOSTICS OF MULTICOMPONENT ETHYL-BENZENE-WATER MIXTURE FUEL PB59. R.Lamari, S.Zougar, R. Kherrat (Univ. Annaba) Electrochemical characterization of an EIS sensor functionalized with �-cyclodextrin for the detection of m-cresol. Characterization by cyclic voltammetry and electrochemical impedance spectroscopy PB60. S.LAMOURI, M. Hamidouche, N. Bouaouadja, V. Garnier, G. Fantozzi (Univ. Sétif, INSA Lyon) Etude de la transformation de la boéhmite vers l’alumine-� par diffraction des rayons X in-situ : effet de la taille des particules sur la formation des alumines de transition PB61. W. Loued, T. Turki, M. Mbarek, J. Wery, K. Alimi (Univ. Monastir, CNRSM, Univ. Nantes) Elaboration of new composite based on poly(lactic acid) and poly(N- vinylcarbazole): combination between experimental analysis and theoretical studyPB62. S. Mabrouk, Y. Braham, H. Barhoumi, A. Maaref (Univ. Monastir) New method based on single-walled carbon nanotube sheets sensor for the determination of tocopherol and the evaluation of the maturation of the Tunisian olive oil using Voltammetric Electronic-Tongue PB63. N. Majoul, S. Aouida, I. Madhi, M. AOUIDA, B. BESSAÏS (CRTEn, CB) Fonctionnalisation du silicium poreux par le 3-aminopropyltriethoxysilane pour la détection des glycosides cyanogènes PB64. M. Bergaoui, C. Aguir, A. Nakhli, M. Khalfaoui, M. F. M’henni, A. Ben Lamine (Univ. Monastir) Adsorption of bovine serum albumin (BSA) on polystyrene and its copolymers controlled by quartz crystal microbalance PB65. M. Bergaoui, A. Nakhli, C. Aguir, M. Khalfaoui, M. F. M’henni, A. Ben Lamine (Univ. Monastir) Theoretical modeling of adsorption isotherms of bovine serum albumin (BSA) on polystyrene and its copolymers PB66. N. Maouche (Univ. Sétif) Ion imprinted polypyrrole for selective and sensitive determination of lead ions PB67. A.MEDJALDI ; A. HIMOUR; S. ABDERRAHMANE et A.GHARBI (Univ. Annaba) Caractérisation des revêtements de Zinc par métallographie et méthodes électrochimiques PB68. I. Naimi, N. Bellekhal (INSAT) Modified carbon felts as efficient cathode for electro-Fenton process: Application to degradation of Fluoxetine in aqueous medium PB69. M.El.F. Nehal, A. Bouzidi, A. Nakrela, H. Tabet-Derraz, M. Medles, R. Miloua, N. Benramdane, R. Desfeux, C. Mathieu (Univ. Sidi-bel-Abbès, Univ. Artois) Propriétés structurales et optiques des couches minces WO3-x fabriquées par la technique Spray Pyrolysis PB70. S. OUCHENANE, S. ABDERRAHMANE, K. ABDERRAHIM, S. ATHMANI et A. GHARBI (Univ. Annaba) Etude de l’effet synergique de deux inhibiteurs Y(NO3)3.6H2O et LaCl3.7H2O sur la corrosion de l’acier au carbone A37 dans NaCl 0,5M PB71. Y. Ouennoughi and B. Bouzerafa (Univ. Sétif) Cyclic voltammetry investigation of new symmetrical tetradentate cobalt(II)-Schiff base complex with the effect of the solvent medium on the redox properties - Electrocatalytic reduction towards some alkyls halides

PB72. A. OULABBAS, S. ATHMANI, Y. Hamlaoui (Univ. Annaba) UTILISATION DES TERRES RARES COMME INHIBITEURS DE CORROSION DES ACIERS BAS CARBONES PB73. A.S. Pavluchenko, A.L. Kukla, A.V. Mamykin, N.V. Konoschuk, O.Yu. Posudievsky (NAS Ukraine) QUANTITATIVE ESTIMATION OF COMPOSITION OF ORGANIC SOLVENT VAPOR MIXTURE WITH ELECTROCONDUCTING POLYMER SENSOR ARRAY PB74. N. Rachedi (Univ. Boumerdes) Effet d’un revêtement métallique sur les propriétés de l’acier ferrito-martensitique Fe-12Cr PB75. W. Argoubi, M. Saadaoui, C. Mayorga, A. Merkoçi and N. Raouafi (Univ. Tunis, UA Barcelona) Disposable biosensing platforms based on nanostructured SPCEs modified by ferrocene-tethered to clustered-gold nanoparticles PB76. M. A. Ben Aissa, B. Tremblay, A. Courty, K. Boujlel, and N. Raouafi (Univ. Tunis, UPMC Paris) Size- and shape-controlled synthesis of copper nanoparticles and their self-organization into 2D and 3D assemblies PB77. M. Haddaoui and N. Raouafi (Univ. Tunis) Tyrosinase/ZnO nanoparticle-modified SPCE biosensor for the detection of ppb levels chlortoluron based on the phenol oxidation inhibition PB78. A. Hammami, N. Raouafi and K. Boujlel (Univ. Tunis) Naphtoquinonethiol self-assembled monolayers on gold electrode as a biosensor for indirect selective and sensitive detection of dopamine PB79. A. Mars, A. de la Escosura, W. Argoubi, N. Raouafi and A. Merkoçi (Univ. Tunis, UA Barcelona) A disposable label-free immunosensor for the sensitive detection of an Alzheimer’s disease biomarker (ApoE) based on LbL self-assembled ferrocene-modified AuNPs on SPCEs PB80. A.Sedik , S.Abderrahmane, S.Boukerche, S.Ouchenane, A.Gharbi (Univ. Annaba) SCANNING MICROELECTROCHEMICAL CHARACTERIZATION OF THE ANTI-CORROSION PERFORMANCE OF INHIBITOR FILMS FORMED BY L-METHIONINE ON COPPER PB81. A.Sedik , S.Abderrahmane , S.Ouchenane, Sameh Athmani, K.Abderrahime and A.Himour (Univ. Annaba) The investigation of synergistic inhibition effect of L-methionine and cysteine on the corrosion of copper in nitric acid solution PB82. D. Smail, S. Chaoui, T. Zerkak, D. Benachour, B.Djellouli (Univ. Sétif) Effet de la montmorillonite brute et modifiée sur les propriétés du blend polypropylène/Amidon plastifié PB83. S. Tiaouinine, M. Boumedjout, L.Kaboub, N. Kahla, H. Ghreib, A.K. Gouasmia (Univ. Tebessa, Univ. Sétif) Élaboration et caractérisation de nouveau matériau moléculaire : 2-[5-(amidocarbonyl)-1,3-dithiol-2-ylidene]-5-[4,5-bis(pentylthio)-1,3-dithiol-2-ylidene]-1,3,4,6-tétrathiapentanlène-TCNQF4 PB84. O.Tobbi, K. Guerfi, N. Rebbani (Univ. Annaba) The surface characteristics of inorganoclay and their effect on immobilization of Cr(VI) from aqueous medium PB85. A. Touati, M. Benounis, M. Bourourou and H. Barhoumi (Univ. Khenchela, Univ. Monastir) ELECTROCHEMICAL SENSOR BASED ON MODIFIED GLASSY CARBON ELECTRODE FOR THE DETECTION OF ZINC IN WATER PB86. M. Tounsi, M.Braiek, B. Ben Hassine, N. Zine, N. Jaffrezic-Renault, M. Gorsane, A. Maaref, and A. Errachid (Univ. Monastir, Univ. Lyon) A novel potassium chemical sensor based on 7 helicene as a ligand PB87. M. Tounsi, M.Braiek, H. Barhoumi, B. Ben Hassine, M. Gorsane, N. Zine, N. Jaffrezic-Renault, A. Maaref, and A. Errachid (Univ. Monastir, Univ. Lyon) Chemical Sensor Based on Polypyrrol-Helicene Derivatives deposit on a Glassy Carbon Electrode for Alkali ions Detection PB88. F. YNINEB, M.R. KHELLADI, D. MENDIL, D. GUITOUME and A. AZIZI (CDTA Alger, Univ. Sétif) Growth time effects on the electrodeposition of well-aligned ZnO nanorod arrays PB89. C. Ayadi, S. Hbaieb, R. Mlika, H. Ben Ouada, Y. Chevalier, R. Kalfat (INRAP, Univ. Monastir, Univ. Lyon) PANI pseudopolyrotaxane as new conducting material: application to potentiometric sensor PB90. A. Zazoua, H. Fourou, N. Jaffrezic-Renault (Univ. Jijel, Univ. Lyon) Fonctionnalisation d’une électrode en Or par la �-Galactosidase pour la détection impédimétrique du Plomb dans les eaux usées PB91. A. ZAZOUA, S. Bouraoui, N. Jaffrezic-Renault (Univ. Jijel, Univ. Lyon) Caractérisation et performance d’un biocapteur pour métaux lourds développé à partir d’une électrode en or fonctionnalisée par une membrane polymère à base de polyflavonoïdes PB92. S.Zougar , R. Lamari, S.Baali, R. Kherrat, N.Jaffrezic Renault (Univ. Annaba, Univ. Lyon) ELABORATION DE CAPTEURS A MEMBRANES INDICATRICES D’IONS - APPLICATION A LA DETECTION

DU BLEU DE METHYLENE PB93. H. Zrida, K. Hriz, N. Jaballah, M. Majdoub (Univ. Monastir) Nouveau polymère �-conjugué dérivé de carbazole contenant l’isosorbide dans la chaine latérale PB94. H. Zrida, K. Hriz, N. Jaballah, M. Majdoub (Univ. Monastir) Nouveau polymère �-conjugué dérivé de naphtalène contenant une chaine latérale polaire PB95. N. Ktari, N. Fourati, C. Zerrouki, M. M. Chehimi, R. Kalfat (Univ. Monastir, CNAM Paris, Univ. Paris-Est) Nouveau capteur gravimétrique MIP-SAW pour la détection d’antibiotiques dans les milieux aquacoles PB96. I. Rassas, M. Braiek, A. Chrouda, H. Majdoub, A. Maaref and N. Jaffrezic-Renault (Univ. Monastir, Univ. Lyon) Electrochemical Behavior of platinum electrode modified with a sulfated polysaccharide (carrageenan) PB97. M. Ben Ismail, H. Feracci, J.P. Salvetat, N. Casañ-Pastor, E. Solar Perez, A. Soltani, M. Souiri, A. Othmane (Univ. Monastir, Univ. Bordeaux, Univ. Barcelona) Indium-tin Oxide surface conditioning for E-cadherin protein binding PB98. Z. Mazouz, B. Aziza, N. Fourati, C. Zerrouki, R. Mghaieth, R. Kalfat, A. Othmane (Univ. Monastir, INRAP, CNAM Paris) Réalisation et étude de substrats poreux fonctionnalisés en vue de la réalisation d’un capteur d’ADN pour la détection d’une mutation localisée au niveau d’une seule base PB99. D. Ayed, M. Souiri, A. Othmane (Univ. Monastir) Enzyme immobilization in a modified membrane structure: performance study and application in biosensors PB100. A. Bennour-Ben Abdeljelil, M. Souiri, M. Oudni-M’rad, S. M’rad, H. Babba, A. Othmane (Univ. Monastir) Elaboration and characterization of Echinococcus granulosus immunosensor PB101. R. Ben Ali, H. Ben Ouada, N. Sakly, A. Othmane (Univ. Monastir) Potentiometric algal biosensor for the measurement of Cd2+ based on immobilized whole cell Picocystis salinarum PB102. O. Chinguiti, A. Moadhen , H. Dridi , L. Haji (Univ. Tunis, ENSSAT Lannion) Gold nanoparticles deposited on oxidized porous Silicon as a Surface-Enhanced Raman Scattering (SERS) active substrate PB103. N. Zehani , P. Fortgang, M. Sadek Lachgar, F. Bessueille, R. Kherrat, N. Jaffrezic-Renault (Univ. Lyon, Univ. Annaba) Electrochemical detection of Bisphenol A by enzymatic biosensor based on tyrosinase modified boron doped diamond electrodes PB104. N. Zehani,S. V. Dzyadevych, R. Kherrat , N. Jaffrezic-Renault (Univ. Lyon, Univ. Annaba, NAS Ukraine) Ultra-sensitive conductometric biosensor for online measurement of diazinon PB105. M. Braiek, E. A. Sapountzi, J.F. Chateaux, F. Vocanson, F. Lagarde, A. Maaref, N. Jaffrezic-Renault (Univ. Lyon, Univ. Monastir) Impedimetric biosensor based on electrospun PEI/PVA decorated with gold nanoparticles for glucose detection PB106. E. A. Sapountzi, M. Braiek, J.F. Chateaux, F. Vocanson, N. Jaffrezic-Renault, F. Lagarde (Univ. Lyon, Univ. Monatir) Development of a novel platform based on electrospun PVA-SbQ-GOx Nanofiber Mats exploiting MWCNTs for glucose detection PB107. R. Damiche, M. Baitiche (Univ. Sétif) EFFET D’UNE MATRICE HOTE SUR LA SOLUBILITE D’UN PRINCIPE ACTIF EN MILIEU ACIDE PB108. S. Khlifi, A. Rouis, M. Echabaane, I. Bonnamour, H. Ben Ouada (Univ. Monastir, Univ. Lyon) Preparation and characterization of azo-calix[4]arenes/SWCNTs nanocomposite thin films PB109. A. Mami, I. Mellouki and N. Yacoubi (IPEIN Nabeul) Thermal characterization of textiles by photopyroelectric technique PB110. S. Chaibi, T. Hadjersi, A.Seddik El Hak., N. Yaakoubi, N.. Zine, N. Jaffrezic-Renault, A. Errachid (Univ. Boumerdes, Univ. du Maine, Univ. Lyon) Label-free impedance biosensor for detection of interleukin-1 antigenPB111. A. Soussou, I. Gammoudi, F. Moroté, P. Négrier, M Hamami, D. Mondieig, Z.M. Baccar, A. Kalboussi, C. Grauby-Heywang, T. Cohen-Bouhacina (Univ. Bordeaux, Univ. Monastir, INRAP) Morphologies and crystallographic structure of Layered Double Hydroxide nanomaterials for biosensing applications PB112. N. ZABAT, M. ABBESSI (Univ.Annaba) UTILISATION DES HETEROPOLYANIONS LACUNAIRES POUR L’ELIMINATION D’UN EFFLUENT METALLIQUE : APPLICATION SUR LE CADMIUM PB113. M. Saadaoui, M. Braiek, K. Boujlel, N. Jaffrezic-Renault and N. Raouafi (Univ. Tunis El Manar, Univ.

Lyon) A new ferrocenyl-iminopropyl-modified silica nanoparticle-based platform for the electrochemical biosensing of glucose PB114. A. Rabti, C. Mayorga, A. Merkoçi and N. Raouafi (Univ. Tunis El Manar, ICN & ICREA Barcelona) Highly ferrocene-functionalized graphene for the design of a sensitive sensing of hydrogen peroxide PB115. N.Aoun, F.Echouchene, H.Belmabrouk, P.Temple-Boyer (Univ. Monastir, LAAS Toulouse) 2D numerical modeling of a pH-ISFET PB116. A. Larbi , H. Dahman, M. Kanzari (ENIT Tunis, Univ. Gabès, IPEI Tunis) Effect of substrate temperature on structural and optical properties of the new high absorbent Sn3Sb2S6 thin films PB117. S.Boukerche, S.Abderrahmane , A.Sedik, A. Himour, S.Ouchenane et A.Gharbi (Univ. Annaba) Inhibition de la corrosion du cuivre dans HNO3 à 1M par la L-méthionine sous l’effet de la température

20h00 Banquet

Vendredi 7 Novembre 2014

Session A5 : Sol-Gel et ZnO

8h30 A51. Conférence-cléL. Berthod, V. Gâté, Y. Jourlin, M. Langlet, F. Vocanson, C. Veillas, I. Verrier, O. Dellea (Univ. Saint-Etienne, INP Grenoble, CEA-LITEN) Ecriture de réseaux de diffraction sur couches sol-gel fonctionnalisées photogravables par lithographie optique

9h00. A52. M. Hjiri, R. Dhahri, L. El Mir, S. G. Leonardi, A. Bonavita, G. Neri (Univ. Gabès, Univ. Messina, IMSIU Riyadh) CO sensing properties of Ga-doped ZnO layer prepared by sol-gel route

9h20 A53. A. Tabib, W. Bousslama, H. Elhouichet, M. Férid (CNRSM, Univ. Tunis) Effect of Na doping on structural and optical properties of ZnO nanoparticles 9h40 A54. I. Chaki, M. Boujnah, A. Belayachi, T.El Bahraoui, A. El Kenz , A. Benyoussef , and M. Abd-Lefdil (Fac. Sci. Rabat) Influence of Er concentration on electrical, structural and optical properties of Yb-ZnO films by spray pyrolysis

10h00 A55. F. Tricot, F. Vocanson, D. Chaussy, D. Beneventi, N. Destouches (Univ. Saint-Etienne, INP Grenoble) Elaboration de couches minces nanocomposites sur support souple par voie sol-gel

Session B5 : Capteurs Chimiques II

8h30 B51. Conférence clé Jean-François CHATEAUX, Université Claude Bernard Lyon 1 Nanofibers produced by electrospinning: Principle, implementation and applications

9h00 B52. I. Barto�, V. Mat�jec, J. Mrázek (NAS CR) Highly-reflective coatings prepared on planar substrates and inside silica tubes by sol-gel method 9h20 B53. J. Zajíc, L. Traplová, V. Mat�jec, M. Pospíšilová, I. Barto� (NAS Czech Republic) OPTICAL pH DETECTION WITH U-SHAPED FIBER-OPTIC PROBES AND ABSORPTION TRANSDUCERS

9h40 B54. D. Ahamadou, M. Siadat, E. Losson, M. Lumbreras (Univ. Lorraine) Parfumerie de luxe : détection de fraude ?

10h00 B55. K. Tahri, T. Saidi, M. Bougrini, H. Barhoumi, N. El Bari, A. Maaref, N. Jaffrezic-Renault, B. Bouchikhi (Univ. Meknès, Univ. Monastir, Univ. Lyon) Discrimination and Detection of Adulteration of Tunisian Virgin Olive Oils by Using a Voltammetric Electronic Tongue

10h20 : Pause-café

Session A6 : Capteur a fibre optique

10h40 A61. A. Maaoui, M.Haouari, Z. Zaaboub, H. Ben Ouada (Univ. Monastir) Optical characterizations of an erbium doped tellurite glass

Session B6 : Biosystèmes II

10h40 B61 I. Gammoudi, M. Mathelié�Guinlet, F. Moroté, C. Grauby�Heywang, D. Moynet, T. Cohen�Bouhacina (Univ. Bordeaux) AFM study of SiO2 nanoparticles bacteria interaction for used nanoparticles based sensor

11h00 A62. V. Mat�jec, I. Kašík, O. Podrazký, I. Barto� (NAS Czech Republic) BRAGG FIBERS FOR ABSORPTION-BASED SENSING

11h20 A63. F. Goutaland, N. Ollier, T. Tite, M. Sow et F. Vocanson (Univ. Saint-Etienne) Echange d’ions et poling thermique pour la fonctionnalisation de surface de verre avec des nanoparticules métalliques. Détection d’espèces chimiques par effet SERS

11h40 A64. M. Benounis, B. Petitjean, N. Jaffrezic (Univ. Khenchela, Univ. Lyon)Nouveau capteur à fibre optique de corrosion en zone humide appliqué aux structures en alliages légers 12h00 A65. H. Mahdhi, Z. Ben Ayadi, J. L. Gauffier, K. Djessas and S.Alaya (Univ. Gabès, INSA Toulouse, Univ. Perpignan, King Faisal University) Effects of sputtering power and film thickness on properties of GZO thin films prepared by rf-magnetron

on pathogenic bacteria elimination

11h00 B62. M. Souiri, N. Blel, A. Omezine, A. Othmane (Univ. Monastir, CHU Sousse) Elaboration of an electrochemical immunosensor for the detection of Prostate Cancer Biomarker

11h20 B63. M. Braiek, E.A. Sapountzi, J.F. Chateaux, F. Lagarde, N. Jaffrezic-Renault (Univ. Lyon , Univ. Monastir) Preparation and characterization of electrospun PVA-SbQ nanofiber mats incorporation MWCNTs for biosensor applications

11h40 B64. M. Braik, C.Dridi, M. Ben Ali, M. Ali, M. Abbes, N. Jaffrezic Renault, A. Errachid (Univ. Monastir, Univ. Sousse, NRC Cairo, Univ. Lyon) Development of perchlorate sensor for thyroid cancer diagnostic: A comparative study 12h00 B65. S. Merzouk,J. Bausells, M. Sigaud, N. Jaffrezic-Renault, A. Errachid and N. Zine (Univ. Lyon, CNM Barcelona) Novel hybrid uISE for detection of lithium-ion

12h20 : Remise du Prix du meilleur Poster Clôture des 9èmes Journées Maghreb-Europe

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�� Anthony P.F. Turner

Biosensors & Bioelectronics Centre, Linköping University, S-58183, Sweden. [email protected] www.ifm.liu.se/biosensors

The adoption of screen printing for the production of enzyme electrodes proved to be a decisive element in the success of home blood-glucose monitoring. Until then, biosensors had been wholly hand made, and could not possibly address a market requiring billions of devices a year. Coupled with the use of hand-held digital instruments, proprietary mediators and patented capillary-fill designs, machine fabrication of enzyme electrodes enabled the paradigm changing switch to the electrochemical devices that now dominate this market. Today, approximately half of the electrodes used in disposable glucose sensors are screen printed using curable polymer inks, while the remainder are produced by vapour deposition. Further advances in 3-D printing and printed electronics now make it timely to consider printing not just the senor, but the entire instrument. This talk will explore a state-of-the-art combination of these technologies in the form of an all-printed sensing instrument where everything is produced on a simple sheet of PET or paper to form a disposable, credit-card like device. This platform is being used to develop a range of new products, principally for medical diagnostics, but also for food safety analysis, environmental monitoring and security applications. The combination of advanced semi-synthetic and synthetic receptors with nanomaterials, promises to facilitate a growth in personalised analytical solutions that are widely available to the consumer and that can capitalise on the ubiquitous telecommunications and information systems that are now both widely available and rapidly evolving. The convergence of technologies taking place at the moment prompts a radical rethink of how we deliver healthcare and support currently, and paves the way for a much more person-orientated service that takes into proper account individual physiology and empowerment in a new outcomes-driven paradigm.

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Turner, A.P.F. (2013), Biosensors: sense and sensibility. Chemical Society Reviews �� (8), 3184-3196.

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H. BOUCHRIHA Faculté des Sciences de Tunis, Campus Universitaire 2092 - El Manar Tunis

Le 20ème siècle a été le siècle de l’électronique qui a révolutionné notre vie quotidienne par l’émergence de technologies de pointe et par une course vers la miniaturisation qui a ouvert l’ère de la nanotechnologie. Mais cette miniaturisation est limitée par la résistance des fils, l’échauffement des circuits et la célérité de transfert du courant qui est gouvernée par la vitesse des électrons.

On a alors pensé à suppléer le courant par la lumière car les photons peuvent traverser un milieu diélectrique plus rapidement que les électrons sans freinage ni interaction mutuelle. Toutefois la propagation est toujours gouvernée par les propriétés physiques du milieu et il s’agit de trouver des milieux permettant une diffusion cohérente et donc une propagation guidée et maîtrisée. Une bonne alternative est offerte par les cristaux photoniques.

La domestication, la manipulation et le contrôle des photons bouleverseront alors la technologie du futur et feront du 21ème siècle, le siècle de la lumière et du triomphe de l'optique et de la photonique.

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�A. Benkouider1, A. Ronda1, L. Favre1, M. Naffouti1, M. Abbarchi1, D. Lockwood2, N. Rowell2, A.

Delobbe3, P. Sudraud3 , I. Berbezier1*

1 IM2NP, CNRS, AMU, Marseille, France 2 Measurement Science and Standards, National Research Council, Ottawa Ontario K1A 0R6, Canada3Orsay-Physics, 95 Avenue des Monts Auréliens - ZA Saint-Charles - F - 13710 Fuveau

* presenting author, e-mail: [email protected]

Le silicium est le matériau phare de l’industrie microélectronique car il offre des caractéristiques physiques toujours inégalées en termes d’oxyde, de dopage (à la fois type P et type N), de transport électronique et d’abondance dans la nature. Néanmoins depuis quelques décennies l’industrie microélectronique se heurte au défi technologique de l’intégration des composants optoélectroniques dans la technologie CMOS. Par ailleurs, l’émission de lumière par des nanostructures à base de Si présente une importance capitale car elle répondrait au besoin de sources de lumière pour la photonique silicium. Dans ce contexte, différentes études ont essayé d’associer le Si à d’autres matériaux et en particulier au Germanium, qui forme avec le Si an alliage totalement miscible. Malheureusement, à la fois le Si et le Ge ont une bande interdite indirecte ce qui les rend très inefficaces comme émetteurs de lumière et bien que l’émission de lumière ait été démontrée à très basse température, elle reste très faible à température ambiante à cause de la dissociation de l’exciton.L’ingénierie de bande interdite a été proposée comme une voie prometteuse pour lever ce verrou technologique. Récemment il a été démontré théoriquement que différentes structures à base de Si composées soit d’un empilement de couches ultra-fines de Si et de Ge avec ou sans périodicité [1, 2], superréseaux, nanocristaux, ou nanofils cœur-coquille permettent de créer des métamatériaux à gap direct. Nous montrerons différents exemples de structures susceptibles de produire un gap direct et nous montrerons leur réalisation expérimentale ainsi que leur caractérisation électrique et optique [3]. Nous montrerons les capacités de la gravure directe par faisceau d’ions focalisés en utilisant une source d’alliage métallique liquide (LMAIS-FIB) pour la fabrication de ces structures.

Références:1. M. d’Avezac, J.-W. Luo, T. Chanier, and A. Zunger, Phys. Rev. Lett. 108, 027401 (2012) 2. H. J. Xiang, B. Huang, E. Kan, S.-H. Wei, and X. G. Gong, Phys. Rev. Lett. 110, 118702 (2013) 3. A. Benkouider, A. Ronda, et al. Nanotechnology 25 (2014) 335303

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A.Merkoçi

ICREA & Catalan Institute of Nanoscience and Nanotechnology (ICN2), Bellaterra (Barcelona), Catalonia, Spain

E-mail:[email protected] www.icn.cat

*1�� Nanomaterials (NM) with electrical and optical properties are playing a key role in the design of cutting edge biosensing technologies. Electrocatalytic, plasmonic and quantic properties of NMs such as gold nanoparticles, quantum dots or graphene while operating in simple plastic or paper matrix in diagnostic and safety/security applications will be shown. The effect of the platform architecture and other chemical and physical parameters upon biosensing and actuation including nano/micromotors pick-up or mixing operations will be discussed. The developed smart nanobiosystems are with interest for integration of diagnostic with therapies (nanotheranostics) or sensing and destruction/removal (sensoremoval) for health and environment industries. Examples related to protein (ex. neurodegenerative disease biomarkers), DNA (pathogen related) or cells (cancer cells) with interest for point of care applications will be shown. The developed devices and strategies are intended to be of low cost while offering high analytical performance in screening scenarios beside other applications. Special emphasis will be given to lab-on-a-chip platforms with integrated electrochemical detection with interest for either clinical or environmental monitoring (including sensoremoval). In addition simple paper-based platforms that operate in lateral flow formats with interest for heavy metals or protein detection will be shown. Various enhancement technologies ranging from microfluidics architectures changes, in-chip re-circulations as well as actuation via nano/micromotors able to either pick-up analytes or improve reaction medium in solid-liquid phase sensing technologies will be discussed.

��1. C. Parolo, A. Merkoçi, “Paper based nanobiosensors for diagnostics”, Chem. Soc. Rev., 42 (2013), 450—457 2. A. M. Lopez_Marzo, J. Pons, D. A. Blake, A. Merkoçi, “All-Integrated and Highly Sensitive Paper Based Device with Sample Treatment Platform for Cd2+ Immunodetection in Drinking/Tap Waters”, Anal. Chem., 85 (2013), 3532–3538 3. E. Morales-Narváez, A. R. Hassan, A. Merkoçi, “'Graphene oxide as a pathogen-revealing agent: sensing with a digital-like response', Angew.Chem.Int.Ed. 52 (2013), 13779 –13783. 4. E. Morales-Narváez, H. Montón, A. Fomicheva, A. Merkoçi, “Signal Enhancement in Antibody Microarrays Using Quantum Dots Nanocrystals: Application to Potential Alzheimer’s Disease Biomarker Screening”, Analytical Chemistry, 84 (2012), 6821�6827 5. A. Escosura-Muñiz, A. Merkoçi, “Nanochannels Preparation and Application in Biosensing”, ACS Nano 6 (2012), 7556–7583 6. C. C. Mayorga-Martinez, L. Hlavata, S. Miserere, A. López-Marzo, J. Labuda, J. Pons, A. Merkoçi. “An integrated phenol ‘sensoremoval’ microfluidic nanostructured platform”, Biosensors and Bioelectronics, 55 (2014), 355–359 7. E. Morales-Narváez, M. Guix, M. Medina-Sánchez, C. C. Mayorga-Martinez, A. Merkoçi, “Micromotor Enhanced Microarray Technology for Protein Detection”, Small 2014, 2542–2548. 8. E.Morales-Narvez, A.-R. Hassan, A. Merkoçi, Graphene Oxide as a Pathogen-Revealing Agent: Sensing with a Digital-Like Response, Angwandte Chemie, 52, 13779–13783, 2013

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Sergio BiettiLNESS and Dip. Scienza dei Materiali, Università di Milano-Bicocca, via Cozzi 55, I-20125 Milano, Italycurrent affiliation: L-NESS and Politecnico di Milano, via Anzani 42, I-22100 Como, ItalyE-mail: [email protected]

The semiconductor quantum dot (QD) intermediate band solar cells (IBSC) design introduce an extensionof the absorption coefficient of the host semiconductor to lower energies without voltage loss [1]. The

IBSC working mechanisms have beendemonstrated via Stranski-Krastavov self-assembly of InAs QDs in GaAs, but many issuessuch as strain defect nucleation, increased carrierescape, induced also by wetting layer states, arestill unsolved [2].A different approach is to self-assemble the QDsby droplet epitaxy (DE) [3], a molecular beamepitaxy technique. This technique allows for thegrowth of QDs without the introduction of strain,without a wetting layer, and with the independentcontrol of number density, size and shape. DEalso allows to tune the electronic states,controlling the size and aspect ratio of the QDs.Thus DE is a perfect candidate for the realizationof IBSC. In this presentation the production ofsub-gap two-photon photocurrent in solar cellcontaining lattice matched GaAs/Al0.3Ga0.7AsQDs grown by DE will be shown [4]. By usingDE for QD fabrication it is also possible to tunethe size and the aspect ratio of the QD, to tailorproper electronic levels in order to reduce thetemperature activated quenching of the sub-gapabsorption spectrum of the IBSC (see Fig. 1).Moreover, the lack of defect and wetting layerstates can greatly reduce thermal escape ofcarriers from the QDs [5], leaving photon-induced transitions the dominant ones, as

requested by IBSC theory [1], and avoiding the quasi-Fermi energy pinning to QD states which causes theopen circuit voltage reduction in QD based IBSCs.

References[1] A. Luque, A. Martì, Physical Review Letters, 78, 5014 (1997). [2] A. Luque and A. Martì, Prog. Photovolt: Res. Appl. 9, 73-86 (2001) [3] N. Koguchi and K. Ishige, Japanese Journal of Applied Physics 32, 2052-2058 (1993). [4] S. Sanguinetti, K. Watanabe, T. Tateno, et. al., Applied Physics Letters 81, 613 (2002)[5] A. Scaccabarozzi, S. Adorno, S. Bietti, M. Acciarri and S. Sanguinetti, Phys. Satus Solidi RRL 7, 174-176 (2013)

Fig.1 Upper Panel: normalized external quantum efficiencymeasurement at RT of QD-IBSC with 0.16 (red) and 0.12(black) aspect ratio QDs compared to the no-dot case (blue).Lower Panel: Arrhenius plot of the subgap two-photonphotocurrent, showing that thermal escape is reduced for largerdots.

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�a LATSI Laboratory, Faculty of the Technology, University Saad Dahlab Blida, BP270, 09.000, Algeria

b Institut d’Electronique, de Microélectronique et de Nanotechnologie (IEMN), UMR CNRS 8520, Université des Sciences et Technologies de Lille 1, Avenue Poincaré, BP 60069,

59652 Villeneuve d’Ascq, France [email protected]

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R. Benabderrahmane Zaghouani a), L. Manai, B. Dridi Rezgui and B. Bessaïs

Photovoltaic Laboratory, Research and Technology Centre of Energy, Borj Cedria Science and Technology Park, BP N° 95, 2050 Hammam-Lif, Tunisia

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a) Electronic mail: [email protected]

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Silicon-based solar cells remain the main candidate in photovoltaic solar energy conversion [1]. However, a large part of the solar cell conversion-efficiency limits are attributed to the optical losses in silicon material. Conventionally, the surface reflectivity of silicon-based solar cells can be reduced by texturing the front side of the cell and/or using appropriate antireflection (AR) coatings.� However, these approaches don’t always lead to the lowest reflectivity and to the lowest surface recombination velocity. Several groups have investigated the field of plasmonics, which showed a high potential to enhance the efficiency of wafer-based [2] and thin-film solar cells [3] by using metallic nanoparticles. The performance improvement of such cells is attributed to an increase of the optical path through a scattering mechanism from the metallic nanoparticles and to the increase of the optical absorption within the semiconductor via the enhancement of the localized electric field. This work reports on the parameters that can influence the controlled growth of silver nanoparticles (Ag-Nps) intended to be used in silicon-based solar cells. Ag-Nps were deposited onto silicon substrates using Electroless Metal Deposition (EMD) in HF/AgNO3 solutions. The effect of the solution concentration and deposition time on the structural and optical properties of Ag-Nps was investigated. The nanoparticles were characterized by optical UV-VIS-NIR spectroscopy and Scanning Electron Microscopy (SEM). Optical measurements show that the total reflectivity decreases in the UV-VIS-NIR spectral region. In the UV-VIS region, this behavior can be explained by the interaction of the surface plasmons of the Ag-NPs, while in the NIR region it was attributed to light scattering from the Ag-Nps at the silicon substrate surface. SEM analysis shows that the variation of HF and AgNO3 concentrations leads to the growth of Ag-NPs having different average size and surface coverage.

[1] M.A. Green, Crystalline and thin-film silicon solar cells: state of the art and future potential, Sol. Energy. 74 (2003) 181-192.

[2]: D.M. Schaadt, B. Feng, E.T. Yu, Enhanced semiconductor optical absorption via surface plasmon excitation in metal nanoparticles, Appl. Phys. Lett. 86 (2005) 063106. �[3] Y. Shi, X. Wang, W. Liu, T. Yang, R. Xu, Multilayer silver nanoparticles for light trapping in thin film solar cells, Appl. Phys. Lett. 113 (2013) 176101.�

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1University Mohammed V-Agdal, Faculty of Sciences, Physics Department, LPM, B.P. 1014, Rabat, Morocco.

*Corresponding author: [email protected]�

*1��

In the present work pure ZnO, In doped ZnO (IZO) and (In, F) co-doped ZnO (IFZO) films were successfully synthesized on glass substrates by the chemical spray technique at 350°C, without any additional surfactant or catalytic agent. The effect of dopant concentration ratio on the structural, optical and electrical properties was studied. X-ray diffraction analysis indicates that the films have polycrystalline nature and some differences in the intensity of the peaks and preferential growth, depending on the doping ratios, were observed. No extra phases involving zinc, indium and fluorine compounds were observed. The grain size of the films decreased from 49.1 nm for undoped ZnO to 31.5nm for (In, F) co-doped films. The deposited films showed an average transmittance above 70%, in the wavelength range of 450-700 nm. A minimum electrical resistivity, in the order of 5.0×10-2�.cm was obtained. Such results make these films suitable for photovoltaic and sensor applications.

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�,�� 3��8, Ghada Hamdoun, Sami Saidi and Abdellatif Belhadj Mohamed

Photovoltaic Laboratory Research and Technology Centre of Energy, Borj-Cedria Science and Technology Park, BP 95, 2050 Hammam-Lif, Tunisia.

*Corresponding author: [email protected]

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Single walled carbon nanotube (SWCNTs)/ poly(vinylidene fluoride) (PVDF) nano-

composites are prepared by solution sonication. We have studied optical, structural and

dielectric properties of (SWCNTs)/ PVDF with different proportions of CNT (1%, 2%, 3%

and 5%).

The electrical conductivity increases with increasing concentration. The average value

of the obtained conductivity is about 4.10-6 S.cm-1. Using the UV-Vis spectroscopy the

estimated optical band gap is about 4 eV.

FTIR spectrum has revealed that carbon nanotube alters the crystallinity of PVDF and

thereby enhances the �-phase in PVDF. This enhancement of �-phase is a function of carbon

nanotube concentration

Dielectric measurements at room temperature can be discussed in terms of an

equivalent circuit model designed as a parallel resistor RP and capacitor CP network in series

with resistor RS. We extract numerical values of these parameters by fitting experimental data.

=�� ;��$ single walled carbon nanotube, Polyvinylidene fluorid, nanocomposites,

Dielectric measurements

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�1 IM2NP, UMR 7334, CNRS, Aix-Marseille Université, 13397 Marseille, France

2 Orsay-Physics, 13710 Fuveau, France 3 IFN-CNR, LNESS laboratory, 22100 Como, Italy

*Auteur correspondant : [email protected]

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A22. Temperature effect on morphology and optical properties of ZnO nanoparticles synthesized by sol-gel

method=��+�� (1,*), I. Najeh (1), R. Dhahri (1), J. El Ghoul (1,2), L. El Mir (1,2)

1 Laboratory of Physics of Materials and Nanomaterials Applied at Environment (LaPhyMNE), Gabes University, Faculty of Sciences in Gabes, Gabes, Tunisia.

2 Al Imam Mohammad Ibn Saud Islamic University (IMSIU), College of Sciences, Department of Physics, Riyadh 11623, Saudi Arabia.

Corresponding author: [email protected]

*1��

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Pure hexagonal wurtzite ZnO nanoparticles for different thermal treatment

temperatures were prepared by using sol-gel method for potential applications in the

renewable energy devices. The structural properties showed that the ZnO nanoparticles

exhibit hexagonal wurtzite structure. Thus, in the case of thermal treatment at 500 °C in air,

the powder with an average particle size of 40 nm shows a strong luminescence band around

384 nm in the UV range. However, the optical band gap of our samples varied between 3.34

and 3.21 eV with increasing annealing temperature. The characteristics of crystallinity,

morphology and optical properties of ZnO nanoparticles were investigated.

=��>��$ Zinc oxide; Nanoparticles; Sol-gel; Optical materials;

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Mostefaoui Mohammed1,2,*, Mazari Halima2, Khelifi Seyfallah1,

Bouraiou Ahmad1, Dabou Rachid1

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1Unité de Recherche en Energies Renouvelables en Milieu Saharien URER/MS d’Adrar,

Le Centre de Développement des Energies Renouvelables (CDER), Algérie. 2 Département d’électronique, Université Djillali Liabès de Sidi Bel-Abbes,

22000 Sidi Bel-Abbes, Algérie.

*�Adresse�mail�([email protected])�

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Desert areas are of course best suited to photovoltaic power generation due to abundant availability of sunlight throughout the year. But the accumulation of dust particles on the surface of photovoltaic (PV) panel greatly affects its performance especially in the Dust storms. In this study, the effect of dust on the performance of photovoltaic modules (isofoton-100w) in a region of the Sahara (URER-MS ADRAR) is analyzed. We evaluate the variation depending on the dust of electrical characteristics such as I-V and P-V curves of PV modules exposed to the extreme weather conditions in desert area. In particular, power efficiency of Photovoltaic Modules deteriorated by around 10% for a dust exposure of 60 days only.

=��>��$�Photovoltaic module, photovoltaic (PV) module performance parameters, dust effect.�

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1.Laboratoire des Semi-conducteurs et Dispositifs Electroniques, unité C3S,Ecole Supérieure des Sciences et Techniques de Tunis.

5, av. Taha Hussein, Montfleury, University of Tunis, Tunisia. 2. Centres des Recherches et Technologies de l’Energie. Technopole Borj Cédria B.P N°95-

2050 Hammam-Lif,Tunisia.

*e-mail: [email protected]

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*1��

Due to the increasing of the electric energy consumption, researchers tried to find new technologies for producing electricity. Among these technologies, dyes-sensitized solar cells (DSSCs) are used as an alternative to conventional solar cells due to their low cost and easy fabrication procedures. Flexibles dyes sensitized solar cells offer some advantages over compared to those based on rigid glass substrates due to its high flexibility and light weight. The flexible plastic substrates (Indium Tin Oxide coated polyethylene naphthalate (ITO/PEN) is a candidate to replace the rigid glass substrates due to its high transparency, high thermos-stability, low moisture permeability and high chemical stability. These factors make ITO/PEN a good candidate for fabrication of DSSCs.

We have prepared the TiO2 electrodes using a paste containing TiO2 nanoparticles dispersed in solvents by using doctor blading technique. The TiO2 films deposed on the tin conductive oxide (TCO) glass substrates are sintered at 450°C to remove the binders in the films and solidify TiO2. But for the preparation of the TiO2 films deposed on plastic substrates (ITO/PEN), we have limit the thermal treatment to 150°C and we have limit the using of organics binders who does not evaporates at low temperature below 400°C.

We have studied the topology of these films by x-ray diffraction (XRD)and X-ray photoelectron spectroscopy (XPS). The XRD peaks for the TiO2 films deposited on TCO substrate at 25.53°, 37.96°, 48.32°, 55.28° correspond to anatase (1 0 1), (1 1 2), (2 0 0), (2 1 1) crystal planes. The XRD peaks for the TiO2 films deposited on plastic substrate ITO/PEN at 25.67°, 38.11°, 48.47°, 55.43°correspond to anatase (1 0 1), (0 0 4), (2 0 0), (2 0 1) crystal planes.

We have synthesized and used naturel dye extracted from the cactus pears and organic dye (phthalocyanine) as sensitizers of TiO2 electrodes. The absorption spectra of the extracted dye diluted in ethanol or distilled water and the phthalocyanine dye diluted in Dimethyl Formamide (DMF) were measured using UV–Vis spectrophotometer. The maximum absorbance of the cactus pears diluted in distilled water was found in the blue close to 280 nm and other in the green close to 535.5 nm. The absorption of the TiO2 thin films immersed in natural and organic dye was measured in order to tune the changes. DSCCs were realized using the two types of substrate and the obtained parameters were compared.

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1. Laboratoire des Semi-conducteurs et Dispositifs Electroniques, unité C3S, Ecole Supérieure des Sciences et Techniques de Tunis.

5, av. Taha Hussein, Montfleury, University of Tunis, Tunisia

e-mail : [email protected] * [email protected]

*1��

Photovoltaic (PV) cells technology reaches a considerable growth in the last decades due to necessity of green energy to reduce greenhouse effect by exploiting free solar energy. Extensive researches have been done using recent discovered technologies and materials. Dye-Sensitized Solar Cells (DSSCs) present one of the promising PV energy offering inexpensive manufacturing technology. Compared to inorganic solar cell, DSSCs are significantly different in their principle of operation and structure.

To improve new solar cell power conversion and material efficiency, monochromatic External Quantum Efficiency (EQE) also called incident monochromatic photon to electron conversion efficiency (IPCE) is a necessary step. EQE was studied using computerized lock-in amplifier, chopper, monochromatic lamp and USB controlled monochromator. Chopping frequency was studied and response time was determined for lab build DSSC to obtain EQE characteristics.

In this work, I-V characteristics of DSSC were extracted using built-in lab solar simulator. Combination of two light sources was studied and tested using commercially available low cost materials. Low voltage halogen lamp and high power light emitting diode (LED) are studied. Temporal stability was extracted through optical measurement using lens, pyro-electric detector and a lock-in amplifier digitized with Labview software. Intensity was decreased about 5% after six working hours. As well spectral response was obtained through optical measurements by adding a digital controlled monochromator to the last set-up. Spectral distribution of the halogen lamp was a weak power in the ultraviolet zone for that we combined a LED lamp to enrich this zone and minimizing the similarity error comparing to the sun. Irradiance power was measured for both sources using calibrated solarimeter.

In order to reach a suitable testing area four halogen lamps with reflector were used, in perpendicular form, enhanced with high power LED in the middle of the cross. I-V measurements were done after calibration of irradiance power, angle of irradiation, distance between sources and PV cell and power source. Results of measurements are discussed and solar simulator efficiency and classifying was specified. The correlation between EQE of DSCC and spectral absorption of dye was done.

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�Nejmeddine JABALLAHa, Jean-Louis FAVEb, Mustapha MAJDOUBa

a Laboratoire des Interfaces et Matériaux Avancés (LIMA), Faculté des Sciences de Monastir, Bd. de l’Environnement, 5019 Monastir, Tunisia. b Institut des Nanosciences de Paris (INSP), UMR 7588-CNRS. Université Pierre et Marie Curie (UPMC), 4 place Jussieu, case 840. 75252 Paris Cedex 05, France.

Deux polymères semi-conducteurs à base de systèmes �-conjugués séparés de type poly(p-phénylène vinylène) (PPV) ont été synthétisés via la polycondensation de Wittig (�2�et ��). Leurs analogues comportant des groupements cyano (CN) sur les unités vinylènes ont été préparés par la polycondensation de Knoevenagel (�2"�) et ��"�)). Les structures macromoléculaires de ces polymères ont été confirmées par spectroscopies RMN et FT-IR. Leurs propriétés optiques ont été étudiées par spectroscopies UV-visible et de fluorescence, en solution diluée et sous forme de couche mince. Leurs niveaux d’énergie frontières HOMO et LUMO ont été déterminés par voltamétrie cyclique. ��

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Une étude comparative de l’absorption de ces polymères en solution montre qu’une cyanation du vinylène a pour effet de réduire la planéité des séquences PPV et de diminuer considérablement la longueur effective de conjugaison. L’ampleur de cet effet stérique du cyano dépend étroitement de la flexibilité au niveau du groupement espaceur (�) et détermine la structure électronique et le comportement optique des polymères de type cyano-PPV. En effet, quelle que soit la nature du groupement espaceur, une diminution du niveau HOMO a été observée comme résultat de la réduction de la conjugaison et de l’effet mésomère accepteur de CN. En revanche, le niveau LUMO augmente dans le cas de l’espaceur encombrant isopropylidène (�2"�)) et diminue dans le cas du groupement sulfure relativement flexible (��"�)). Ainsi, la cyanation du système PPV se manifeste par un déplacement vers le bleu de l’absorption et une augmentation du gap optique du matériau. Ces résultats montrent que dans le cas de ces polymères à chromophores séparés l’effet stérique hypsochrome de CN l’emporte son effet électronique bathochrome, contrairement au cas des PPVs totalement conjugués. Par ailleurs, l’analyse des spectres de fluorescence indique un déplacement bathochrome de l’émission sous l’effet de l’incorporation de CN. Ceci s’accompagne également d’une diminution du rendement de fluorescence et d’un renforcement des interactions interchaînes à l’état solide. Mots-Clés : polymères semi-conducteurs ; poly(p-phénylène vinylène) ; effet du cyano ; effet espaceur ; propriétés optiques. �

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F. Mezianea, V. Raimbaulta, H. Hallila, S. Jolya, L. Bechoua, D. Rebièrea, C. Dejousa

aUniv. Bordeaux, IMS, CNRS UMR 5218, IPB, 351 Cours de la libération, F-33405 Talence, France e-mail: [email protected]; [email protected]�

*1��The selective detection of heavy metals, such as transition metals, is of great importance for environment monitoring and medicaldiagnosis. Optical sensors offer an attractive and convenient way to overcome the limitations of conventional techniques, generally expensive and time-consuming, by offering label free analyte detection, fast sensor response, real time measurements of analytebinding processes and a high level of integration. In this work we address the challenging task of the feasibility of an optical sensor for Cr (VI) heavy metal colorimetric determination with diphenylcarbazide using polymeric materials compatible with further integration on Electro-Wetting On Dielectric (EWOD) microfluidic chips that we have recently developed. Photonic sensors are generally basedon the fundamental principle of light–analyte interaction. The aim is to convert the presence of chemical or biochemical analytes into an analytical and measurable optical signal. In conventional photonic sensors based on linear waveguides, the interaction lengthcorresponds to the physical length of the sensor. Thus implying that transmission-based techniques are usually not well considered while working on small optical paths, as it is the case in microfluidics [1].

By contrast, one of the ways to increase the effective optical path length is to use resonant devices such as Optical MicroringResonators (OMR). Such a device can produce more compact sensors with a reasonably high sensitivity that does not directly dependon the device length. Resonant peaks appear when light wavelength is an integral number of times the microring perimeter due toconstructive interferences. As the light at these resonant peaks travel into the ring multiple times, the effective optical path length is dramatically increased, leading to a high sensitivity to any perturbation of the surrounding medium. While OMRs are commonly used as Refractive Index (RI) sensitive devices, their application to absorption measurement has recently been demonstrated [2]. Thecombination of OMRs with microfluidic systems represent a promising way for the development of a new generation of field-deployable environmental sensors or Point Of Care (POC) diagnostic tools. We describe our work on design, fabrication and characteristics of polymer OMR sensor with novel materials, which possess well suited optical properties for optical sensing applications in liquid environments.

The remainder of this work is structured as follows: first, the sensor principle using visible-beam evanescent absorption spectroscopy is explained. Second, in order to achieve a precise numerical simulation of the OMR design, the experimental characterization (the imaginary part � and the real part n of Cr (VI)-1,5 diphenylcarbazide complex) was performed to inject in the simulation software. The integrated absorption based OMR sensing device was designed to maximize interaction with a cladding fluid (Cr (VI)-1,5 diphenylcarbazide complex) in the visible range. Our simulation demonstrates that the shift of the resonance peak position at the drop port due to reel refractive index (n) depends on the Cr (VI) concentrations. Moreover, the change of the imaginary part K value,strongly affects the transmitted power, and signal attenuation increases at resonance due to absorption. In real application, these shifts would originate from the variation of detected metallic ions concentration. Finally, we provide an outlook and conclusion based on the obtained results.

Figure 1.A Photograph of Prototype EWOD test device on glass plate and board for electronic control (left), focus on actuation electrode path (right) and shematic of the OMR (Bottom).

[1] V. M. N, Passaro, B. Troia, M. La Notte and F. De Leonardis, Photonic resonant microcavities for chemical and biochemical sensing, RSC Advances, 3, 25-44(2013).

[2] A. Nitkowski, A. Baeumner, and M. Lipson, On-chip spectrophotometry for bioanalysis using microring resonators, Biomed. Optic. Express 29�271– 277 (2011).

*�C�>��$�The authors would like to thank D. Bassani at the Institut des Sciences Moléculaires-Bordeaux laboratory, for the spectroscopy absorption measurements and J. Toudert and V. Ponsinet at the Centre de Recherche Paul Pascal-Bordeaux for spectroscopic ellipsometry measurements. �

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Algérie *Corresponding author : [email protected]

2Laboratoire des Sciences des Matériaux pour l’Electronique et d’Automatique, Université Blaise Pascal de Clermont II, Les Cézeaux, 63177, Aubière Cedex, France.

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��#��\��?��Université de Monastir, Faculté des sciences de Monastir, Département de physique, Laboratoire des Interfaces

et des Matériaux Avancés, 5019Monastir, TUNISIA. Université de Sousse, Institut Supérieur des Sciences Appliquées et de Technologie de Sousse, Cité Ettafala,

4003 Ibn Khaldoun Sousse, TUNISIA. *��ª|\��>�

¥��$�\��\��Centre National de Recherches en Sciences des Matériaux, Laboratoire de physico-Chimie des

Matériaux Minéreaux et leurs applications, B.P. 95 Hammam-Lif, 2050, TUNISIA. ��

Université Sud Toulon Var, Institut Matériaux Microélectroniques Nanosciences de Provence Site de Toulon BP 13283957 La Garde Cedex, FRANCE.

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A43.�Study�of�Optical�Behavior�of�Compound�Semiconductors�(ZnO/Co3O4)�in�Thin�Layers�Obtained�by�Spray�Pyrolysis�Technique�

K.M.A. Boureguig , H. Tabet-Derraz, A. Bouzidi, N. Benramdane.

[email protected],�[email protected], [email protected],�

[email protected]�

Laboratoire d’Elaboration et Caractérisation des Matériaux (LECM), Département d’électronique, Faculté des Sciences de l’Ingénieur, Université Djillali Liabès, B.P. 89,

22 000 Sidi Bel- Abbès, Algérie.

*1��$�

The aim of this work is to produce in first step, form of films, two types of binary semiconductors which are: ZnO and Co3O4 by the method of spray pyrolysis [1] thin films obtained at temperatures around 300° C. In our study, the ZnO compound crystallizes in the wurtzite configuration, its lattice parameters are [a = 3.224 Å, c =5.202 Å] and its grain size was estimated at about 205 Å, As against the Co3O4 compound crystallizes in the spinel cubic configuration with the lattice parameter is a= 8.0345 Å and its crystallite size of 650 Å. Optical properties are discussed after measuring the transmittance T and reflectance R in the range of visible region. In our optical study, the ZnO has a direct bandgap of 3.27eV, for against the Co3O4 has a share in a direct gap is estimated at 1.98 eV, and the other an indirect gap ranging from [2.15 - 2.20eV], this transition is assisted by a phonon of 0.05eV. A second step would be that to use a method of approximate calculation of the effective mediums to predict the evolution of the optical parameters resulting from the mixture of pure materials. Regarding the gaps , it was found that the models predict the existence of the gap of Co3O4

to 2.1 eV and that of ZnO near to 3.2 eV for concentrations: x = 0.5 and x = 0.6. This way of working allows us to have, before depositing thin films, particularly optical characteristics of the chosen composite.

=�� >��: Spray pyrolysis, (Co3O4 - ZnO) thin films, X-ray diffraction, optical measurements and optical parameter, gaps, permittivity, composites, method of effective medium approximation, effectives parameters .

��[1] M. Mitsuya et S. Imazeki, Rev. Sci. Instr. 61, 2466(1990).�

[2] E.M. Bachari , G. Baud , S. Ben Amor, M. Jacquet, Thin Solid Films, 165, 348(1999).

[3] R. Drasovean, S. Condurache-Bota, optoelectronics and advanced materials,Vol . 11, No. 12, December

2009, p. 2141 – 2144.

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1. ��·�}��¯�}��·�}��}��¯��!��³�� ³��"��·�}��Tunable deep-level emission in ZnO nanoparticles via yttrium doping, Journal of Alloys and Compounds, 509, 3606-3612,(2011).

�� #�¦�� #�� # � �� =!�� »�� Fluorine doped zinc oxide thin films deposited by chemical spray, starting from zinc pentanedionate and hydrofluoric acid: Effect of the aging time of the solution, Materials Science and Engineering B, 174,�46–49,(2010).�

�� «�� ¯��³�� ¥��}�� Room temperature ferromagnetism in Tb doped ZnO nanocrystalline films, Journal of Magnetism and Magnetic Materials, 324, 642-644 (2012).�

�� \��\�²��²��\��²��|¨�� ·��²\�¦ ��}\��?�²��\��On the properties of indium doped ZnO thin films, Semiconductor Science and Technology, 20, 120–126, (2005).�

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a,b,c Laboratoire de micro-optoélectroniques et nanostructures, Faculté des Sciences de Monastir,

Université de Monastir, Avenue de l’Environnement 5000 Monastir, Tunisie

a Institut Préparatoire Aux Etudes d'Ingénieurs de Kairouan, Université de Kairouan, Tunisie

d,e Laboratoire Multimatériaux et Interfaces. Université Claude Bernard Lyon 143, Boulevard du 11

Novembre 1918, France

[email protected]

*1��$

Structural and optical studies of BxInyGa1-x-yAs/GaAs quantum wells, grown by Metal

Organic Vapor Phase Epitaxy (MOVPE), have been achieved by High resolution X ray Diffraction

(HRXRD) and Photoluminescence spectroscopy (PL). An important fraction of indium has been

incorporated into BGaAs which show that a BxInyGa1-x-yAs can be grown lattice matched to GaAs.

Temperature dependence of the BInGaAs PL peak energy and Integrated Intensity have been

studied. At low temperature we have shown an abnormal phenomenon. Based on these results, we

have suggested that the carrier recombination mechanisms in the BInGaAs QWs result from

exciton-localization like mode. This behavior is attributed to the localized states induced by the

clustering of the boron atom in BInGaAs QW.

=��>��$ BInGaAs, clustering, lattice matched, localization, MOVPE

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aLaboratory of Photovoltaic, Research and Technology Center of Energy, Technopole of Borj-Cedria,

BP 95, Hammam-Lif, 2050 Tunis, Tunisia

Corresponding author:��1��C��D��

�

*1��

Owing to wide variety of applications of graphene, high quality and economical way of synthesizing

graphene is highly desirable. In this study, we report a cost effective and simple approach to

production of high qualitygraphenenanosheet. Here, the synthesis route is bases on electrolytic

exfoliation of graphite. Instead of using strong acids (which oxidize and damage the geometrical

topology of graphene), 11 ml of alkaline solution (30% KOH)) was added in distilled water

containing 4.8 g of (98% H2SO4) and considering as electrolyte.

The structure and properties of the obtained graphene were characterized via X-ray diffraction

(XRD), Fourier transform infrared spectroscopy (FTIR) and Raman Spectroscopy. X-ray diffraction

analysis suggests that the graphenenanosheets were exfoliated into a monolayer or few-layers,

resulting a new lattice structure, which is significantly different from graphite to graphene.

We review recent results on the Raman spectroscopy and imaging of graphite and graphene. We

focus on the origin of the D and G peaks and the second order of the D peak. The G and 2D Raman

peaks change in shape, position and relative intensity with the number of graphene layers. This

reflects the evolution of the electronic structure and electron-phonon interactions.

Keywords: Industriel graphite; Graphène; Electrochemical exfoliation; Raman Spectroscopy

w��%�*@�/]Q@^Q�^;/�^]<?[]Q+Q]/=Q>[�+Q+<��]>^?<*@=[]^*[^|Q==*;��Q;�*@^?<*@@>;<=/Q=

{|*?*�]>}>`;Q={>];<?|*�]>{|<Q*{?<�[Q

��#��\�� !¼�� ·��}�� ?��aUniversité de Lyon, F-42023 Saint-Etienne, France; CNRS, UMR 5516, Laboratoire Hubert Curien, F-42000

Saint-Etienne, France bLaboratoire des Matériaux et de Génie Physique (LMGP) – UMR CNRS 5628, Grenoble INP,

F-38000 Grenoble, France cL2CE, Laboratoire des Composants pour le Conversion de l’Energie, CEA/LITEN, Laboratoire d’Innovation pour les

Technologies des Energies Nouvelles et des nanomatériaux, F-38054 Grenoble, France

*Auteur correspondant : [email protected] ��

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a University of Mohammed V-Agdal, Faculty of Sciences, Materials Physics Laboratory, B.P. 1014, Rabat, MoroccoÙniversity Mohammed V-Agdal , Faculty of Sciences, Laboratory of Magnetism and High Energies Physics , B.P. 1014,

Rabat, Morocco

*Corresponding author: [email protected]

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BRAGG FIBERS FOR ABSORPTION-BASED SENSING

Vlastimil Matějec, Ivan Kašík, Ondřej Podrazký, Ivo BartoňInstitute of Photonics and Electronics AS CR, v.v.i., , Chaberská 57,

182 51 Praha 8-Kobylisy, Czech Republic Phone: +420 266 773 511; Fax: + 420 284 680 222; e-mail: [email protected]

Recently, photonic crystal fibers (PCFs) have been tested for chemical sensing [1].Such fibers consists of a solid or hollow core surrounded by a cladding of regularly arranged air holes. Due to the photonic band gap effect light in a certain range of frequencies is confined in the fiber core and it is guided in it while light with frequencies outside the range is refracted in the cladding. Provided that detected chemicals are dawn in the cladding or core air holes they change the imaginary refractive index in these parts and such changes can be detected in the output signal from the fiber. PCFs are usually prepared from pure silica. However, there is a special kind of PCFs so called Bragg fibers (BFs) in which light is confined into a solid or hollow core due to the photonic band gap effect on pairs of a high-index and low-index layers (so called Bragg layers). The cladding of Bragg fibers is made of glass (usually doped silica). In the case of a BF with a hollow core it can be filled in with detected chemicals and used for sensing. Some results measured with BFs with a hollow core filled in with solutions of a pH indicator bromothymol blue are presented in this paper.

Bragg fibers were prepared by the MCVD method. High-index Bragg layers were fabricated from silica doped with germanium oxide while low-index layers from silica slightly doped with phosphorous pentoxide. The refractive-index contrast between these layers was of about 0.03. The theoretical modeling of Bragg fibers was carried out. On the basis of results of this modeling three pairs of the high- and low-index layers were deposited on the inner wall of a silica substrate tube with thicknesses making possible the light guidance in a hollow fiber core within a wavelength range of 500-700 nm. BFs with an outer diameter of 170 μm and a hollow core diameter of about 50 μm were drawn from tubes with the deposited Bragg layers.

Prepared fibers were characterized by optical microscopy (see Figure) and by measuring angular distributions of output power from the fiber excited by an inclined collimated beam. For testing the sensitivity of the fibers to changes of the light absorption coefficient, solutions of bromothymol blue in the Sorensen buffer solutions with different pH were filled in the hollow core of the fiber. The core was illuminated from a halogen lamp and the spectrum of the output power from the fiber was measured with an Ocean Optics diode array spectrometer. The measured spectra and the calibration curve drawn from them will be presented in the paper and compared with those measured on the bulk indicator solutions.

.This work was financially supported by the Czech Science Foundation (contract No. 102/12/2361).

[1] A.M. R. Pinto et al., Photonic crystal fibers for sensing applications, J. Sensors Volume 2012, Article ID 598178, 21 pages

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PROKOPIV T.1, SMUTOK O.1, ERRACHID ABDELHAMID2, GONCHAR M.1,3

1Institute of Cell Biology, NAS of Ukraine, Drahomanov Street 14/16, Lviv 79005, Ukraine 2�Laboratory of Analytical Sciences, UMR CNRS 5180, Claude Bernard Lyon 1 University, F-69622

Lyon, France 3Institute of Applied Biotechnology and Basic Sciences, Rzeszow University, Sokolowska Str. 26,

Kolbuszowa, Poland

e-mail: [email protected]; [email protected]

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Université Claude Bernard Lyon 1, Institut des Sciences Analytiques, UMR CNRS-UCBL-ENS 5280,5 rue de la Doua 69100 Villeurbanne, France

e-mail : [email protected]

Le développement de nouveaux nanomatériaux a fait l’objet de recherches intensives ces dernières années. Ces structures de taille submicrométrique, qui possèdent une forte surface spécifique et peuvent servir de plateformes pour le greffage de fortes densités de molécules chimiques ou biologiques, trouvent des applications dans de nombreux domaines dont celui des biocapteurs. Les nanomatériaux communément utilisés pour le développement de biocapteurs électrochimiques sont constitués de nanoparticules métalliques (or, argent,…), de nanotubes, de nanofils ou de nanobaguettes de carbone, de graphène ou de nanofibres. D’importants progrès ont également été réalisés dans l’élaboration de matériaux nanocomposites combinant ces nanomatériaux à différents types de biomolécules et de polymères, conducteurs ou non, en vue d’une amélioration des processus de transfert électronique et de transport à l’interface électrode modifiée/électrolyte.

Dans cette présentation, nous ferons tout d’abord un rappel sur les nanomatériaux et nanocomposites utilisés pour l’élaboration des biocapteurs électrochimiques (nature, synthèse, caractéristiques, fonctionnalisation) puis nous nous attacherons aux nouvelles avancées dans le domaine en illustrant par plusieurs exemples tirés d’études menées au laboratoire.

�!�!��Y. Xiao, Chang Ming Li, Nanocomposites: From Fabrications to Electrochemical Bioapplications, Electroanalysis, 20 ( 2008) 648- 662 A.J. S. Ahammad, J.-J. Lee, Md. A. Rahman, Electrochemical Sensors Based on Carbon Nanotubes, Sensors, 9(2009) 2289-2319 I.Willner,; B. Willner, Biomolecule-based nanomaterials and nanostructures. Nano Lett.�10 (2010) 3805–3815 S. A. Ansari, Q. Husain, Potential applications of enzymes immobilized on/in nano materials: A review, Biotechnol. Adv., 30 (2012) 512–523 R. S. Dey, R. K. Bera,C. R. Raj, Nanomaterial-based functional scaffolds for amperometric sensing of bioanalytes, Anal Bioanal Chem 405 (2013)3431–3448

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Anna Miodek1, Michel Gomgnimbou2, Christophe Sola2 Hafsa Korri-Youssoufi1*

1 Equipe de Chimie Bioorganique et Bioinorganique, Institut de Chimie Moléculaires et Matériaux d’Orsay, Université Paris-Sud, Orsay, France. E-mail : [email protected]

2 Equipe Infection Génétique Evolution des Pathogènes Emergents, Institut de Génétique et Microbiologie, Université Paris-Sud, Orsay, France

Des nanomatériaux formés de nanotubes de carbones multi-feuillets (MWCNT) revêtues de polypyrrole (PPy) et de dendrimères PAMAM redox ont été constitués de façon simple et utilisé comme transducteur moléculaire pour des biocapteurs d'ADN. L’adressageélectrochimique est la voie la plus prometteuse puisqu’il s’agit d’une déposition contrôlé et reproductible qui s’adaptent aux systèmes miniaturisés. Le composite NTC-PPy a été ainsi formé en enroulant le film de polypyrrole sur MWCNTs pendant la polymérisation électrochimique du pyrrole sur une électrode en or. La couche NTC-PPy a ensuite été

modifiée avec des dendrimères redox de PAMAM de quatrième génération (PAMAM G4) qui sont liés de manière covalente au matériau composite par électro-oxydation des amines. Le composite MWCNT-PPy-PAMAM a été caractérisée par microscopie électronique à balayage (MEB), spectroscopie infrarouge spectroscopie (FT-IR) et spectroscopie de photoélectrons X (XPS) pour démontrer la morphologie ainsi que la structure moléculaire de ce matériau.

La détection d'hybridation de l’ADN spécifique pour le virus de l'hépatite C avec des séquences cible de 15 ou 75

bases et des sondes d'ADN de 15 bases immobilisées sur la surface du biocapteur a été démontrée par le suivi du transfert d’électrons par voltammetrie cyclique et impédance électrochimique. Ces biocapteurs montrent une forte sensibilité avec une limite de détection de 0.1 femto molaire. Pour démontrer la faisabilité de ces biocapteurs dans des échantillons réels la détection d’ADN issue d’échantillons de PCR de cellules infectées de tuberculoses ont été étudiée. Le biocapteur détecte avec succès l'ADN de la tuberculose 411 bases à partir d'échantillons de PCR. La sélectivité de tels capteurs a été également démontrée par la mesure de l'échantillon de PCR qui ne contenait pas le gène spécifique.

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Mykhailo T. Zhybak1, Lyubov Y. Fayura2, Yuri R. Boretsky2, Mykhaylo V. Gonchar2,

Andriy A. Sibirny2, Eithne Dempsey3, Yaroslav I. Korpan1

1 Institute of Molecular Biology and Genetics, NAS of Ukraine, 03680, Kyiv, Ukraine;

2Institute of Cell Biology, NAS of Ukraine, Drahomanov Str. 14/16, 79005 Lviv, Ukraine; 2Centre for Research in Electroanalytical Technologies, Department of Science, ITT Dublin, Tallaght,

Dublin 24, Ireland [email protected]

Abstract

For the first time, we propose and report amperometric biosensor for sensitive and selective

detection of L-Arginine (L-Arg) based on Nafion/Polyanyline (PANI) composite, commercial

Platinum Screen-Printed Electrodes (PSPE) and novel recombinant Arginine Deiminase from

Mycoplasma hominis, which has been cloned, expressed, purified and used as a biorecognition

element of sensor. The NH4+ ions released during the enzymatic transformation of L-Arg, diffuse

into the PANI layer and provoke the reduction of PANI on the SPCE at a potential of about

�350 mV versus Ag pseudo-reference electrode. The sensitivity of the biosensor was

92±1.5 nA/(0.1 mM/mm2) with the apparent Michaelis–Menten constant of 0.3±0.01 mM derived

from an L-Arg calibration curve. A linear concentration range was observed from 0.005 to 0.1 mM,

a limit of detection being 0.003 mM and a response time — 15 s (90 % of steady-state value). The

developed biosensor revealed a good selectivity to L-Arg and demonstrated good storage stability –

no decrease of sensor signal within a month has been obseved. The proposed amperometric

biosensor has been tested in sample of commercial pharmaceutical “Cytrarginine” and the obtained

L-Arg-content values correlated well with those declared by producers.

*�C�>��: This work was partially funded by the “SMARTCANCERSENS” project from the European Communities Seventh Framework Programme under the Grant Agreement PIRSES-GA-2012-318053 and by the NATO Science for Peace (SFP) Project CBP.NUKR.SFPP 984173.

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aLaboratory of advanced materials and interfaces, Faculty of Medicine, University of Monastir, 5019 Monastir, Tunisia bGroupe Immunité des Muqueuses et Agents Pathogènes (GIMAP), EA 3064, SFR 143, Université Jean Monnet, University of Lyon, F42023, France cRegional Laboratory of Hygiene, University Hospital Farhat Hached, 4000 Sousse, Tunisia d University of Lyon, Institute of Analytical Sciences - CNRS UMR 5280, F69100 Villeurbanne, France Legionella spp. are widespread in natural and anthropic aquatic environments. They may cause a severe pneumonia in humans (Legionnaires’ disease - LD) which may be fatal in almost 20% of cases. Legionella pneumophila is by far the species most frequently associated with Legionnaires’ disease. Detection of Legionella in environmental samples can be made through the use of standardised methods such as cultivation (AFNOR T90-431 or ISO 11731) and PCR (AFNOR T90-471). Both methods are hampered either by their low sensitivity and the time needed to complete the analysis (cultivation) or by their cost and inefficiency to discriminate between live and dead bacteria (PCR). Several attempts have been made to purpose other detection tools such as flow cytometry for instance in a wish to identify Viable But Not Culturable (VBNC) forms of L. pneumophila but this method remains technically demanding. The strategies of L. pneumophila to adapt and resist to stressful environmental conditions not only include interaction with amoebae and biofilm localisation but also the ability to enter into a VBNC state. The existence of VBNC L. pneumophila cells, which may be infectious for humans, in water systems has already been described [1].Thus, there is still a need to set up detection tools that may have the potential to detect VBNC forms.We have previously elaborated an electrochemical immunosensor for detection and quantification of L. Pneumophila [2]. The aim of this study was to elaborate a new electrochemical immunosensor for the detection of VBNC forms of L. pneumophila. Our immunosensor was obtained by the immobilisation of a specific monoclonal anti-L. pneumophila antibody (MAb), on an indium-tin oxide (ITO) electrode – by Self Assembled Monolayers (SAMs) method using an aminosilane (APTES).The immunosensor was first characterized by wettability (contact angle measurement), atomic force microscopy (AFM), confocal laser scanning microscopy (CLSM), electrochemical impedance spectroscopy (EIS) and cyclic voltammetry (CV) in the presence of [Fe(CN)6]4-/3- as a redox probe.AFM images and wettability evidenced the functionalization of ITO surface by SAMs of APTES. CV and EIS demonstrated the immobilization of a MAb layer, acting as barrier for the electron transfer between the electrode surface and the redox species in the solution. VBNC forms of L. pneumophila were obtained from artificial water samples after a heat shock treatment of 30 min at 70°C (as recommended by WHO as a water system disinfection procedure).The absence of culturable forms of L. pneumophila was first evidenced using both ISO 11731 standard and a flow cytometric assay using propidium iodide and SYTO-9 as viability markers [1]. As shown previously, a 30 min treatment at 70°C has left in the samples only dead cells and VBNC forms of L. pneumophila[1]. Specific binding of VBNC L. pneumophila cells on our immunosensor was evidenced by CLSM imaging and EIS. A linear relationship between the change in charge transfer resistance (ÕRct) and the logarithmic concentration value of VBNC was observed in the range of 101 to 104 CFU/mL with a limit detection 101 CFU/mL on artificial samples. In conclusion, this immunosensor based on EIS has the potential to detect L. pneumophila VBNC forms. It may be of interest for water systems surveillance when a contamination by L. Pneumophila is suspected provided that the detection limit observed in artificial samples is confirmed in real environmental samples. Further studies are necessary to evaluate its performance on real samples. =��>��$� Immunosensor; Antibody immobilization; Legionella pneumophila; VBNC; detection; Electrochemical Impedance Spectroscopy. ��$�[1] Allegra S.et al. Appl. Environ. Microbiol., 2008, 74: 7813-7816. [2] SouiriM. et al. Talanta, 2014, 118: 224-230.� This project was supported by “Conseil régional Rhône-Alpes”, France through its COOPERA call for proposals (2012) and by « Action Intégrée Franco-Tunisienne du Ministère des Affaires Etrangères et Européennes français et du Ministère de l'Enseignement Supérieur, de la Recherche Scientifique tunisien » under No. 12G1123 –No. Egide 26443UH.

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B34. Activité électrochimique sédimentaire et son utilisation dans l’épuration des eaux usées Philippe Namour1,2, Lucas Jobin1, Nicole Jaffrezic1

1 Université de Lyon, Université Claude Bernard Lyon 1, Institut des Sciences Analytique, UMR 5280, 5 rue de la Doua, F-69100, Villeurbanne, France 2 Irstea, UR MALY, 5 rue de la Doua, F-69100, Villeurbanne, France

Correspondant : [email protected]

Résumé : Les êtres vivants tirent leur énergie de réactions d'oxydoréduction au cours desquelles une source d'énergie (composés minéraux ou organiques) est oxydée et les électrons extraits alimentent une série de coenzymes. En bout de chaine les coenzymes réduits rejettent leurs électrons dans le milieu vers des accepteurs variables selon le type respiratoire de l’organisme considéré : oxygène (métabolismes aérobie), ou composés minéraux comme nitrate & nitrite, Fe(II), sulfate, gaz carbonique (métabolisme anaérobie). La maitrise de ce flux permanent d’électrons permet d’envisager des applications nouvelles. Lors de la conférence nous aborderons les usages que l’homme peut tirer de l’activité d’oxydo-réduction microbienne d’une part comme extraction d’énergie de ma dégradation de la matière organique (biopile), ou de l’activité microbienne des sédiments (biopile sédimentaire), d’autre part comme capteurs d’activité métabolique (biocapteur d’effets perturbants ou d’effets toxiques), et enfin comme moyen de contrôle des populations microbiennes dans les technique de bioremédiation.

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2 University of Carthage, Laboratory Materials - Molecules and Applications, IPEST, Tunis 2070, TUNISIA *Corresponding author: �� ª|\��

3 Analytical Laboratory, Department of Applied Organic Chemistry, N. R. C., Cairo, EGYPT3 Institute of 4Analytical Sciences of Lyon, ISA, UMR 5280, Université Claude Bernard Lyon 1, FRANCE

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I.Zahou*, S.Touaiti, R.Mlika, R.Ben Chabaane, B.Jamoussi, H.Ben Ouada

Laboratoire des Interfaces et Matériaux Avancés (LIMA), Faculté des Sciences de Monastir

*Corresponding author : [email protected], [email protected]

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B44. Conception et développement de nouveaux microcapteurs chimiques pour la détection des métaux dans les eaux�

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S. Chatti*, A. Fildier, A. Bonhommé, C. Sanglar, P. Marote, O. Boyron, H. Casabianca

Université de Lyon, Institut des Sciences Analytiques, UMR 5280 CNRS, Université Lyon 1, 5 rue de la Doua, 69100 VILEURBANNE, France

*Auteur Correspondant : [email protected]

L’extraction par barreau aimanté absorbant [Stir Bar Sorptive Extraction (SBSE)] est une technique analytique qui consiste à utiliser un barreau aimanté recouvert d’une couche polymérique à base de dérivés de polydiméthylsiloxane (PDMS). Cette technique est principalement utilisée pour l’analyse de contaminants hydrophobes dans les échantillons aqueux. Dans le but d’étendre l’application de cette technique d’extraction à d’autres matrices, nous avons synthétisé de nouvelles phases à base de diverses huiles de silicones (fonctionnelles et non fonctionnelles) qui pourront être utilisée pour des molécules d’intérêt avec des polarités très variées.

Avant d’étudier l’efficacité de ces barreaux, nous avons effectué la déformulation de diverses huiles silicones à l’aide de techniques analytiques (RMN 1H, 13C et à deux dimensions, MALDI-ToF). Le suivi en ligne par Raman et IRTF de la polymérisation a permis d’optimiser le réseau tridimensionnel afin de l’adapter au mieux à chaque type de molécule cible. Nous avons ensuite optimisé la mise en forme et le conditionnement (solvant, temps de réaction et température).

Les échantillons ayant subis différents types de conditionnement sont ensuite observés en microscopie électronique à balayage (MEB) tant en surface (vue de dessus) qu’en coupe transversale (tranche). Ces observations montrent une variation de la structure. Les vues du dessus font apparaitre une augmentation de la rugosité et des aspérités. Des « nervures » sont de plus en plus importantes et fréquentes avec l’augmentation de l’additif silicone non fonctionnel couplé au conditionnement. Sur les coupes transversales la porosité augmente avec la présence de plus en plus marquée de canaux indiquant une modification de l’architecture de ces matériaux.

Ces nouvelles phases d’extraction présentent beaucoup d’avantage par rapport à d’autres techniques à savoir : un faible coût, une mise en œuvre facile et un traitement ne nécessitant qu’une faible quantité de solvant organique, ce qui rend cette technique respectueuse de l’environnement.

Le premier objectif de ce projet est d’optimiser la polymérisation et la préparation du support. L’incorporation d’additifs dans la phase d’adsorption obtenue permet de modifier l’aspect de surface du polymère. L’étude des techniques de conditionnement permet d’augmenter les aspérités et les performances d’adsorption du support.

Par la suite, ces supports seront testés sur différentes familles de molécules afin d’évaluer la capacité d’adsorption. Les applications pour les meilleurs candidats seront réalisées sur des matrices complexes (alimentaires, cosmétiques, environnementales…).

B46.�MICROENCAPSULATION�PAR�COACERVATION�COMPLEXE�DES�PROTEINES�DU�LACTOSERUM�ET�DE�LA�GOMME�D’ACACIA�

Delphine�ACH,�Stéphanie�BRIANCON,�Guy�BROZE,�Yves�CHEVALIER�

Université�de�Lyon,�Laboratoire�d'Automatique�et�de�Génie�des�Procédés,�Université�Lyon�1,�UMR�5007�CNRS,�43�bd�du�11�Novembre,�69622�Villeurbanne,�France�([email protected]�lyon1.fr)�

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� L’encapsulation� par� coacervation� complexe� est� une� technique� employée� dans� l’industrie�alimentaire�afin�de�protéger�des�ingrédients�fonctionnels�tels�que�les�probiotiques,�les�vitamines,�les�antioxydants�et�les�acides�gras.�La�coacervation�complexe�est�un�phénomène�de�séparation�de�phase�associative� induit� par� des� interactions� électrostatiques� entre� deux� polymères.� Le� couple� de�polymères� le� plus� utilisé� en� coacervation� complexe� est� le� système� gélatine/gomme� d’acacia.�Cependant,� l’utilisation� de� la� gélatine� devient� controversée� pour� les� applications� alimentaires.� Un�substituant� intéressant� à� la� gélatine� est� constitué� par� les� protéines� du� lactosérum,� dont� leur�composant�majoritaire,�la�bêta�lactoglobuline.�

� L'étude� systématique� du� procédé� d'encapsulation� par� coacervation� complexe� a� permis�d'appréhender�l'influence�des�paramètres�de�formulation�de�de�procédé�afin�d'acquérir�une�maitrise�que� la� méthode� empirique� habituelle� ne� permet� pas� d'atteindre.� L'implémentation� d'un� capteur�vidéo�dans�le�réacteur�agité�a�permis�l'observation�in�situ�d'évènements�que�des�mesures�ex�situ�ne�permettent�pas�de�détecter.�

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Ivo Bartoň, Vlastimil Matějec, Jan Mrázek

Institute of Photonics and Electronics AS CR, v.v.i., Chaberská 57, 182 51 Prague 8, Czech Republic

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Dielectric mirrors, called also Bragg mirrors, have been employed for the construction of photonic structures such as Fabry-Perot resonators, Bragg fibers, etc. and used in advanced lasers [1], sensors [2],solar applications [3], etc. Such mirrors are based on the constructive interference of light on a stack of dielectric layers with a high refractive index interleaved with layers of a low refractive index layers at a certain wavelength. At this wavelength the mirror reflectivity is very close to unity if thicknesses and refractive indices of the layers fit necessary physical requirements [4]. Bragg mirrors are usually prepared on planar substrates by physical methods or by sol-gel methods [4]. In sol-gel methods TiO2 has mainly been used for the preparation of high-index layers and SiO2 for low-index ones [3], [4].

This contribution presents results on preparation and characterization of Bragg mirrors on planar substrates and inside silica tubes. These Bragg mirrors consist of high-index layers composed of silica doped with 10 and 20 mol% of TiO2 while the low-index ones are prepared of silica. The thicknesses of the layers was set to achieve a maximum reflectivity at about 550nm.

Bragg mirrors were prepared by sol-gel method. A starting sol for the preparation of the low-index layers was based on tetramethyl orthosilicate (TMOS) dissolved in methanol with the addition of hydrochloric acid and water. The water/alkoxide ratio was of 1.75 and the concentration of alkoxide was c=1mol/l. The sol was aged at 70°C for 30minutes while stirred. The high-index layers were applied from a starting sol prepared by mixing the TMOS sol with second one composed of titanium tetrabutoxide dissolved in isopropanol with addition of nitric acid. The concentration of titanium butoxide in the second sol was c=0,314mol/l. Two sols with different ratios of SiO2-TiO2 9:1 respective 8:2 were prepared.

The sols were applied onto silica slides or onto the walls of silica tubes by using dip-coating technique. The thermal treatment of applied gel layers was done at a furnace at 450°C after the deposition of each layer in order to obtain densified layers with designed thicknesses. One to seven pairs of high- and low-index layers were prepared.

The characterization of coatings was done with UV-VIS-NIR spectrophotometry to obtain transmission spectra in a wavelength range of 190-1100nm. Reflection spectra of coatings were also measured under angles of incidence of 15-60 degrees. The thickness of layers was measured by contact profilometry. Refractive indexes of layers were determined from spectral ellipsometry. Transmission spectra of coatings applied on silica tubes which show interference bands are presented in this contribution. They are compared with those measured on coatings on silica slides. A minimum transmission of bellow 5% was achieved.

This work was supported by the Czech Science Foundation (contract P102/12/2361).

[1] Ratajczak R., et.al., Vacuum, Volume 83, Supplement 1, 1 May 2009, S148-S151[2] Liu, J. et al., Opt. Express 17, 2731-2738, 2009.[3] Almeida, Rui M., et.al.. J. Non-Cryst. Solids. 345-346, 562-569, 2004[4] Almeida,Rui M. el al, Optical Materials 33(12), 1867-1871, 2011

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aJakub Zajíc, aLenka Traplová, bVlastimil Matějec, aMarie Pospíšilová, bIvo BartoňaCzech Technical University in Prague, Faculty of Biomedical Engineering,

Nám. Sítná 3105, 272 01 Kladno 2, Czech RepublicPhone: +420 312 608 223; Fax: + 312 358 419; e-mail: [email protected]

bInstitute of Photonics and Electronics AS CR, v.v.i. , Chaberská 57, 182 51 Praha 8-Kobylisy, Czech Republic

Measurements of pH are broadly employed in industry, agriculture, biology, medicine, etc. In medicine the knowledge of pH value provides us with the information not only about the patient status but also about some details on physiological processes in the patient body. In order to measure pH different sensors including electrical and optical ones are used. Fiber-optic sensors have also been tested for pH monitoring in medicine [1], e.g. for monitoring gastrohageal reflux. They can be easily inserted in medical catheters. Usually, reflection-based fiber-optic probes are used in such measurements which are modified by absorption or fluorescence pH indicators. Although such probes are suitable for practical pH measurements the research and development of pH probes still continues with aims such as suppressing the pH indicator leaching and decomposition or ways for further miniaturization of sensing probes. This contribution presents results of the investigation of optical properties of three absorption pH indicators, namely methyl orange, methyl red and bromothymol blue. The indicators are immobilized in the cladding of U-shaped fiber-optic probes by using matrices of porous silica, porous silica doped with titanium dioxide or ethylcellulose.

Three pH indicators, namely methyl orange (a pH detection range of 3.1-4.4), methyl red (a pH range of 4.4-6.2) and bromothymol blue (a pH range from 6 to 7.6), have been investigated. In order to develop pH sensors indicators were immobilized in layers prepared from alkoxides or from polymer, ethylcellulose. Alkoxide-based layers were fabricated by the sol-gel method from sols based tetrametylortosilicate and titanium tetrabutoxide dissolved in alcohols under the acidic catalysis. Detection layers with thicknesses of about 0.5μm can be prepared from such matrices. The ethylcellulose detection layers were applied from a sol of ethylcellulose in ethanol and toluene with thicknesses of about 100μm. The sols were applied onto microscopic slides and U-shaped fiber-optic probes by the dip-coating method. The applied coatings were dried at 100 °C. U-shaped probes used in experiments were prepared from silica fibers (a core diameter of 400 μm) which were bent in a burner flame to an arch with a diameter of about 2 mm. The arch dimensions were fixed and the arch was coated with a sol or solution containing the tested pH indicators.

Transmission spectra of coated microscopic slides and U-shaped elements were measured by using a halogen lamp as a light source and an Ocean Optics diode array spectrometer as a detector. Slides and U-shaped elements were immersed in buffer solutions with different pH and changes of absorption bands of the indicators were monitored. Temporal changes of measured spectra were also measured. In the contribution spectra of the indicators and calibration curves in aqueous solutions and in the matrices are discussed in terms of the indicator dissociation constant, the detection sensitivity, linearity of the response, etc.This work was financially supported by the project” BIO-OPT-XUV Research Team Advancement at theFaculty of Biomedical Engineering, CTU in Prague, No.” MEYS ESF project CZ.1.07/2.3.00/20.0092”

[1] F. Baldini, Optical chemical sensors, Springer 2006

B5�.�Parfumerie �de�luxe�:�détection�de�fraude�?�

Dia�Ahamadou,�Maryam�Siadat*,�Etienne�Losson,�Martine�Lumbreras�LCOMS,�Université�de�Lorraine�–�Metz�

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Le� problème� de� la� contrefaçon,� notamment� dans� l’industrie� du� parfum,� est� très� préoccupant.�D’où�la�nécessité�de�développer�des�tests�de�contrôle�de�routine,�non�«�invasifs�»,�pour� lesquels� le�nez�électronique�est�une�technique�simple�à�mettre�en�œuvre,�peu�chère,�aux�résultats�aussi�bien�qualitatifs�que�quantitatifs,�selon�l’«�entraînement�»�effectué�en�amont.�

Dans�ce�contexte,�nous�présentons� l’analyse�d’un�parfum�de� luxe,�sous�3�concentrations�commerciales�différentes,�qui�sont�:�parfum,�eau�de�toilette,�eau�de�Cologne.�Ces�déclinaisons�sont�obtenues�par�ajout�d’eau�et�d’alcool,�d’où�un�taux�de�«�fragrance�»�de�moins�en�moins�important.�La�fraude�la�plus�simple�consiste�à�délayer� les�plus�fortes�concentrations.�Pour�cette�analyse�nous�utilisons�un�nez�électronique�conçu�dans�notre�laboratoire.�Il�est�équipé�de�5�capteurs�de�gaz�commerciaux�à�base�d’oxyde�métallique�placés�dans�une� cellule�de�volume�réduit,�et�piloté�par�un�microcontrôleur�Mitsubishi�qui�assure�aussi�bien�la�gestion�des�mesures,�l’acquisition�des�données,�l’analyse�de�résultats.�Un�flux�continu�et�constant�de�20�ml/min�est�insufflé�sur�la�surface�de�l’échantillon�préparé�la�veille�pour�le�lendemain,�afin�d’avoir�une�accumulation�de�molécules�volatiles�près�de�cette�surface.�Le�flux�renvoyé�chargé�de�ces�molécules�volatiles�est�mélangé�à�de�l’air�pur�(20%/80%)�afin�d’éviter�l’empoisonnement�des�capteurs.�

Nous�avons�optimisé�la�méthode�de�mesures�en�choisissant�un�temps�d’exposition�permettant�d’obtenir�le� régime� permanent� de� la� réponse� temporelle� des� capteurs,� quels� que� soient� les� capteurs� ou� la�concentration.�A�partir�de� l’apprentissage� (30�mesures�par�dilution),�nous�avons�étudié� la� stabilité�des�différents� paramètres� représentatifs� transitoires� et� permanents.� La� sensibilité� (valeur�permanente/valeur�de�départ),�présentée�sous�forme�de�signature,�valide�le�choix�des�capteurs�(Fig.�1)�:�certains�sont�plus�sensibles�aux�basses�dilutions,�d’autres�séparent�mieux�les�fortes�concentrations.��

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Fig.� 1�:� Signature� des� 5� capteurs� de� gaz� en�termes�de�sensibilité�(rapport�entre�les�valeurs�finale� et� initiale)� pour� les� trois� classes� de�parfum�(A1,�A2,�A3).��

La�performance�de�discrimination�des�dilutions�a�été�analysée�à� l’aide�de� l’Analyse�en�Composantes�Principales� (ACP)� et� l’Analyse� Factorielle� Discriminante� (AFD).� Nous� avons� obtenu� une� très� bonne�séparation�des�trois�groupes�représentatifs,�avec�un�taux�de�réussite�proche�de�100%.��

Nous� avons� étendu� cette� étude� en� introduisant� un� mélange� d’eau� et� d’alcool� dans� chacune�des� dilutions� commerciales�:� l’analyse� par� AFD� met� systématiquement� en� évidence� l’effet� de� fraude�par�dilution,�en�classant�les�points�représentatifs�de�ces�nouvelles�dilutions�à�la�frontière�de�la�dilution�la� plus� faible� (eau� de� Cologne).� Le� nez� électronique� est� donc� capable� de� détecter� une� fraude� par�dilution.�Les�études�suivantes�que�nous�avons�menées�ont�montré�qu’il�était�capable�de�détecter�un�«�manque�»� ou� un� ajout� d’une� molécule� odorante� primordiale,� en� présentant� des� classes� distinctes�dans�l’espace�discriminant�réduit,�permettant�de�distinguer�un�écart�de�composition.�

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1,LOMA,�Université�de�Bordeaux,�UMR�CNRS�5798,�351�cours�de�la�libération,�33405�Talence�cedex,�France�2�NanoPhyNov�(Cellule�de�transfert�ADERA�–�LOMA),�351�crs�Libération,�33405�Talence,�France�3�BMGC,��Université�de�Bordeaux,�INSERM�U1035,�146�rue�Léo�Saignat,�33000�Bordeaux,�France��Understanding�the�mechanisms�of�interaction�between�nanoparticles�(NPs)�and�microorganisms�such�as�bacteria�is� important�for�many�reasons:�some�toxic�NPs�can�be�used�for�their�bactericide�power,�whereas� others� can� be� used� in� the� design� of� sensors� for� the� selective� detection� of� bacteria.� Toxic�effects�of�NPs�on�bacteria�can�be�due�to�the�formation�of�defects�or�holes�in�their�membrane,�to�the�generation� of� reactive� oxygen� species� or� to� the� dissolution� of� NPs� in� ions� interacting� with� the�metabolism.�Atomic�force�microscopy�(AFM)�[1]�is�a�powerful�method�to�study�the�interaction�of�NPs�with�bacteria:�the�tapping�mode�in�air�enables�not�to�damage�biological�samples,�which�can�be�also�imaged�with�in�contact�mode�in�liquid.�Moreover�AFM�is�able�to�discriminate�between�“hard”�(NPs)�and�“soft”�(bacteria)�materials,� leading�to�a�high�contrast� in�phase�images.�In�this�work,�we�applied�AFM�to�the�study�of�silica�NPs�interacting�with�Escherichia�coli�(E.�coli)�bacteria.�These�bacteria�were�incubated�with�NPs�(previously�dispersed�in�ultra�pure�water�at�a�concentration�low�enough�to�avoid�the�formation�of�aggregates),�and�then�immobilized�either�on�mica�or�on�a�multilayered�cushion�of�polyelectrolytes�(formed�by�the�Layer�by�Layer�method).�Silica�NPs�with�diameters��ranging�from�4�nm�to�200�nm�were�used.�AFM�experiments�were�performed�in�air�after�drying�the�samples�and�also�in�physiological�conditions�(liquid).�In�the�absence�of�NPs,�AFM�images�obtained�in�the�case�of�healthy�bacteria�confirms�the�formation�of�stable�E.�Coli�biofilms,�even�after�several�rinsing�steps,�and�enables�to�determine�their�shape�and�dimensions� (mean� length,� width� and� height� are� 1.8μm,� 1.2� μm� and� 0.15� μm� respectively,� in�agreement� with� previous� results)� [2].� The� morphology� of� bacteria� does� not� change� after� their�incubation�in�the�presence�of�large�NPs�(100�nm�and�200�nm�of�diameter),�suggesting�that�bacteria�are� still� healthy.� In� the� case� of� smaller� NPs,� adopt� more� unusual� spherical� shapes.� Moreover,� the�height�of�some�of� them� is�clearly� lower� than� in� the�case�of�healthy�bacteria,� suggesting� that� these�bacteria�are�emptied�of�their�content.�In�some�cases,�it�is�possible�to�observe�a�partial�collapse�of�the�membrane�on�itself.��These�results�show�that�the�size�of�NPs�is�a�crucial�parameter�in�their�toxicity�mechanism.�NPs�of�100�nm�seem�to�be�too�voluminous�to�cross�the�bacteria�membranes,�which�remain�intact.�However,�the�study�of�the�mechanical�properties,�by�using�the�phase�images,�reveals�changes�in�the�structure�and�organization� of� the� bacteria� wall.� In� the� case� of� smaller� NPs,� the� empty� appearance� of� bacteria�suggests�that�membranes�are�disrupted,�leading�to�the�release�of�cellular�compounds.��References�[1]�A.�Simon,�T.�Cohen�Bouhacina,�M.�C.�Porte,�J.P.�Aime,�J.�Amédée,�R.�Bareille�and�C.�Baquey,�Cytometry�Part�A�54A,�36–47�(2003).�[2]� I.� Gammoudi,� N.� R.� Faye,� F.� Moroté,� D.� Moynet,� Ch.� Grauby�Heywang,� and� T.� Cohen�Bouhacina,� World� Academy� of�Science,�Engineering�and�Technology,�79�(2013)�607��613.�

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_4_95_2.pdf · MADICA 2014 - PROGRAMME Mercredi 5 Novembre 2014 9h00 Ouverture officielle 9h30 Conférence plénière I Anthony TURNER, Professor, Linköping (Suède) Printed Biosensor