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TheAtlasofAnalyticalSig
naturesofPhotographicP
rocesses
COLLODION ON PAPER
Dusan C. Stulik | Art Kaplan
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2 The Atlas of Analytical Signatures of Photographic Processes
The Getty Conservation Institute, 2013 J. Paul Getty Trust
2013 J. Paul Getty rust. All rights reserved.
Te Getty Conservation Institute works internationally to advanceconservation practice in the visual artsbroadly interpreted to include
objects, collections, architecture, and sites. Te GCI serves the conservation
community through scientific research, education and training, model field
projects, and the dissemination o the results o both its own work and the
work o others in the field. In all its endeavors, the GCI ocuses on the creation
and delivery o knowledge that will benefit the proessionals and organizations
responsible or the conservation o the worlds cultural heritage.
Te Getty Conservation Institute
1200 Getty Center Drive, Suite 700
Los Angeles, CA 90049-1684
United States
elephone: 310 440-7325Fax: 310 440-7702
Email: [email protected]
www.getty.edu/conservation
TeAtlas of Analytical Signatures of Photographic Processes is intended or
practicing photograph conservators and curators o collections who may need
to identiy more unusual photographs. TeAtlasalso aids individuals studying
a photographers darkroom techniques or changes in these techniques brought
on by new or different photographic technologies or by the outside influence
o other photographers. For a complete list o photographic processes available
as part o theAtlasand or more inormation on the Getty Conservation
Institutes research on the conservation o photographic materials, visit the
GCIs website at getty.edu/conservation.
ISBN number: 978-1-937433-06-2 (online resource)
Front cover: A. C. Vroman,An Arizona Sky and win Buttes, 1895, gold-toned,
silver collodion photograph. Private collection.
Every effort has been made to contact the copyright holders o the photographs
and illustrations in this work to obtain permission to publish. Any omissions
will be corrected in uture editions i the publisher is contacted in writing.
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Historical Background 4
Identification: Glossy Collodion Paper Photographs 9
Important Variants of the Collodion Process 19
Interpretation Guide 25
CONTENTS
3 The Atlas of Analytical Signatures of Photographic Processes
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COLLODION ON PAPER
English: collodion
French: collodion
German: Kollodiumverfahren
HISTORICAL BACKGROUND
here is no clear inventor o collodion-on-paper photography. Instead, a series o inventors
was responsible or the development and introduction o the process, rom early tests and
experiments to practical, industrially produced photographic material. Among them are Marc
Gaudin (1853), William Henry Fox albot (1854), G. W. Simpson (1865), Jean Laurent and Jos
Martinez-Sanchez (c. 1866), and J. B. Obernetter (186768).
Te collodion-on-paper photographic process (see sample photograph in fig. 1) had a long and
interesting history o development, rom an early idea to the industrial production o different
variants o glossy and matte-collodion photographic papers widely used by both amateur and
commercial photographers between about 1870 and 1930. Afer 1930, it was almost entirely
replaced by many different orms o both POP and DOP silver gelatin photographic papers.
Figure 1 A. C. Vroman,An Arizona Sky and Twin
Buttes, 1895, gold-
toned, silver collodion
photograph. Private
collection.
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Figure 2 shows a historical timeline or the collodion-on-paper photographic process.
Process Description
Early experiments conducted with collodion on paper relied on the use o a heavily sized
paper that was needed to prevent deep penetration o the collodion emulsion into the paper.
(Tough it is not technically correct, the term emulsion was widely used in the nineteenth-century photographic literature on the process.) Photographs created using this early version
o the process still exist and can be ound in a number o museum collections with holdings o
historical photographic materials. Most o the still existing collodion-on-paper photographs were
produced on baryta paperusually industrially madesupplied by merchants o photographic
materials and supplies.
1840
1842 1851
1853
1855
18541865
1866
1884
1895
1867 1885 1893
1930s
1850 1860 1880 1890 1900 1910 1920 19301870
Schnbein discovers collodion
Archer introduces wet collodion negative
M. Gaudin introduces collodion emulsion
Moitessier uses transferred collodion positives
Leptographic Paper (BaSO4) introduced
Machine coating of collodion introduced
Hrdlika Rembrandt (AgCrO4) paper
Ashman introduces self-toning collodion paper
Matte-collodion paper (POP/DOP) introduced
End of collodion-on-paper production
W. H. F. Talbot (?) introduces collodion on paper
Simpson introduces collodion photographs
J. B. Obernetter develops commercial collodion chloride paper
Figure 2 Timeline for the collodion-on-paper photographic process.
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Preparation of the Collodion-Silver Halide Emulsion
he irst step in the preparation o collodion photographic paper was to prepare the
collodion-silver chloride photographic emulsion. he collodion needed or the preparation
o the emulsion was produced industrially by nitrating cotton and dissolving the resulting
cellulose nitrate in a mixture o ethyl alcohol and diethyl ether. his solution was available
rom photography or pharmaceutical supply houses and was called collodion. Relatively early
on, the quality o collodion paper was ound to beneit greatly rom using well-aged collodion,which produced a more uniorm collodion-silver halide emulsion and adhered better to the
paper substrate.
Te collodion emulsion was prepared by mixing collodion with silver nitrate and small amounts
o citric or tartaric acid and by mixing another portion o collodion with alcohol-ether soluble
halides (usually calcium, strontium, or lithium chlorides). Both solutions were then combined
under nonactinic light. Te silver nitrate reacted with alkali or alkaline earth chlorides, orming
microcrystals o silver chloride that were well dispersed in the collodion solution. Some recipes
also called or the use o bromide compounds or chloride and bromide mixtures, resulting in less
requenty used collodion-bromide or collodion-chlorobromide emulsions.
As described here, the process o making the collodion emulsion sounds simple, but it was a
demanding technological operation that required very strict conditions (concentrations o
individual chemicals, temperatures, stirring, and adding individual materials in a precisely
specified order). Small amounts o glycerin or castor oil ofen were added to make the final
emulsion more pliable and less prone to cracking when dry, and to acilitate more uniorm toning
o processed photographs. Baryta-coated paper substrates were then hand coated (beore 1889)
or machine coated (afer 1889) with the collodion emulsion.
Hand Coating of Collodion Photographic Paper
Te collodion-on-paper photographic process was introduced at a time when most amateur and
commercial photographers were well acquainted with the preparation and manipulation o wetcollodion negatives. Te hand coating o the collodion emulsion was similar to the coating o
wet collodion negatives. Te baryta-coated paper substrate was laid on a glass plate and held in
place with the photographers fingers. Te collodion emulsion was poured onto the middle o the
paper, and by rotating and tilting the glass plate, the photographer was able to produce a uniorm
emulsion layer across the paper. I a slightly larger piece o paper was used, the less uniormly
coated edges were trimmed rom the final photograph. Special coating rames were available or
less experienced photographers.
Early manuals describing the preparation o collodion paper usually called or treating the
substrate with a very thin coat o emulsion to yield a more uniorm coating and a more consistent
quality o the final photograph.
Machine Coating of Collodion Photographic Paper
Afer A. Kurtz in Germany introduced, in 1889, a machine or the large-scale mechanical
production o collodion paper, most papers used rom that point on were machine coated.
Industrially produced collodion papers were available rom a number o manuacturers in
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different ormats, packed in boxes with the emulsions ace-to-ace and special straw paper to
regulate moisture content o the paper base and to reduce the paper curling typically ound in
collodion paper photographs. Large rolls o baryta paper substrate were mechanically pulled
through a tub o collodion emulsion and dried in a horizontal tunnel using a stream o hot air.
Te collodion emulsion dried quickly, and the resulting roll o collodion paper was then cut to
the desired ormat and packed or shipment.
A major advantage o collodion paper production was that, unlike gelatin-based photographic
paper, which required a long production line and a complicated arrangement o estoons to
acilitate the slow drying process o the water-rich gelatin, collodion contained organic solvents
and dried quickly. Te production line or the preparation o collodion paper could be rather
short (~120 eet). Disadvantages included the use o highly flammable organic solvents (ether
and alcohol) and the potentially explosive cellulose nitrate. Paper curling is caused by differential
moisture absorption in the collodion and paper substrate. Te collodion layer is virtually water
ree, but the substrate expands when exposed to moisture in the air. Tis results in extreme
inward curling o collodion paper during drying.
Development, Processing, and Post-Processing Treatment of Collodion Paper
Collodion-based photographic papers were POP photographic papers that, similar to albumen or
POP silver gelatin photographic papers, did not require chemical development. Te prepared or
purchased collodion paper was placed under a negative into a photographic copy rame and was
photolytically developed by light exposure. Te subsequent processing (washing and fixing) reduced
the amount o developed silver, so the collodion paper had to be overprinted to achieve the desired
silver density o a final photograph. When removed rom a copy rame, the light-developed image
was washed in water to eliminate the soluble silver salts that remained in the collodion layer.
Te next step is toning. A number o different toning ormulas were prescribed in the nineteenth-
century photographic literature. Most o these recipes called or a borax-gold chloride solution,and some substituted sodium phosphate or sodium tungstanate or the borax. Manuals also
stressed that the toning solution be kept slightly alkaline. Te toning operation o collodion
emulsion photographs seems to be more delicate than the toning o albumen photographs, and
shorter toning times are ofen recommended to achieve more uniorm results.
oned collodion photographs need thorough washing beore fixing. Some manuals recommended
a hardening bath o chromium alum or ormaldehyde to restrict swelling o the gelatin in the
baryta layer, which may later cause adhesion problems o the collodion layer. Fixing o toned
collodion photographs is done using a simple solution o sodium thiosulate in water, and most
published procedures call or longer fixing times (up to 15 minutes). Tis was due to the lowpermeability o water through the collodion layer. Fixed photographs are again washed beore
drying or mounting.
Post-Processing Treatment of Collodion Photographs
Due to curling problems, most collodion photographs can be ound mounted on rigid board. Afer
1870, a great variety o industrially prepared mounting boards became available to both proessional
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and amateur photographers (more on mount ormats, styles, and dating clues can be ound in
the Card Photograph section [orthcoming]). Collodion photographs could be mounted when
still partially wet using water-based mounting mediums or pastes. Glossy collodion photographs
also benefit rom surace burnishing, which produces very glossy photographs. Te burnishing
was done when the photo was still slightly moist. Manuals recommended applying a cold roller
first, then a hot roller to produce exceptionally high-gloss photographs. A roller that was too hot,
however, would usually produce a reddish image. An albumen solution mixed with color-matched
pigments was recommended as a spotting medium or damaged collodion photographs.
Beore the introduction o matte-collodion photographic papers in 1894, i a matte surace was
needed or desired, it was prepared by drying the wet surace o the collodion photograph and
squeegeeing it on a high-quality ground glass plate. A semi-matte finish was also produced by
coating the photograph with a solution o beeswax and kerosene.
Figure 3 shows a schematic cross section o a typical glossy collodion photograph.
Main Application of the Collodion-on-Paper Process
Te collodion-on-paper process was used as an alternative to albumen photographs by amateur
and proessional photographers. Afer 1870, the availability o commercially produced collodionphotographic papers provided a convenient printing medium or amateur photographers who
were working with smaller cameras and commercially made silver glass plate negatives and
wanted to reduce the number o processing steps in the darkroom. Commercial photographers
used collodion papers when producing smaller prints, namely card photographs o various
ormats. Because o their severe curling, collodion photographic papers were rarely used or
producing large-ormat photographs. Tis is why museum collections usually do not have large
holdings o collodion photographs in larger ormats.
Noted Photographers Using the Collodion-on-Paper Process
A. C. Vroman
Bibliography (by date)
Wentzel, F. 1960.Memoirs of a Photochemist. Philadelphia: American Museum o Photography.
Penichon, S. 1999. Differences in Image onality Produced by Different oning Protocols or Matte Collodion
Photographs.Journal of the American Institute for Conservation 38(2): 12443.
Figure 3 Cross
section of a typical
glossy collodion
photograph.
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IDENTIFICATION: GLOSSY COLLODION PAPER PHOTOGRAPHS
Visual Signatures
Visual Characteristics
Because o their strong tendency to curl, most glossy collodion photographs were mounted on
solid matte board (fig. 4). Tese photographs may have an entire range o colors, rom light brown
to dark black-violet, based on whether they were toned (figs. 5, 6). Depending on atmosphericconditionsthe amount o moisture in the air, or examplemany glossy and semi-glossy
collodion photographs show a typical intererence color pattern when viewed at an angle against
a light source (fig. 7).
Many glossy collodion photographs show signs o mechanical damage rom requent handling.
Because the collodion layer is ofen very thin, mechanical scratches penetrate through the entire
layer o collodion into the white baryta layer. Most o the damage maniests as thin scratch lines
in the image that can be examined under a microscope.
Microscopic Characteristics
Microscopic investigation o glossy collodion photographs does not allow the observation o indi-vidual particles o silver. Photogenically ormed silver particles, which are typical or most glossy
collodion photographs, are too small to be detected (igs. 8a8c). he thin layer o collodion might
show mechanical scratches reaching into the baryta layer (igs. 9a, 9b).
Figure 4 Three glossy collodion photographs mounted on solid matte board.
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Figure 5 Unmounted,
untoned glossy collodion
photograph.
Figure 6 Mounted,
gold-toned semi-glossy
collodion photograph.
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Figure 7 Glossy
collodion photograph
displaying a typical
interference color pattern
when held up to a light
source.
Figure 8a Detail of the photograph in fig. 7 at 10
magnification.
Figure 8b Detail of the photograph in fig. 7 at 25
magnification.
Figure 8c Detail of the
photograph in fig. 7 at
40 magnification.
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Fibers o the paper substrate are almost undetectable during microscopic inspection o the Dmin
areas o glossy collodion photographs. Only careul observation o these image areas at relatively
high magnification (40 and 80) allows or the detection o some fibers that are covered by
baryta or appear to be embedded in the baryta layer (figs. 10a, 10b).
Analytical Signatures
XRF
XRF analysis allows the detection o silver and toning elements in glossy collodion photographs
and the confirmation o the presence o the baryta layer under microscopic inspection. Most
proessionally produced glossy collodion photographs were toned, but those done by some
amateurs were not. Figure 11 shows an XRF spectrum o the untoned glossy collodion photograph
Figure 9a Detail of the photograph in fig. 6 at 25
magnification, showing a slight scratch into the
baryta layer.
Figure 9b Detail of the photograph in fig. 6 at 25x
magnification, showing another scratch into the
baryta layer.
Figure 10a Detail of the Dmin area of the photograph in
fig. 6 at 40 magnification, showing fibers in the paper
substrate.
Figure 10b Detail of the Dmin area of the photograph in
fig. 6 at 80 magnification, showing fibers in the paper
substrate.
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in figure 5. Te spectrum shows the presence o silver (Ag) in the image layer and the presence
o both barium (Ba) and strontium (Sr) in the baryta layer.
wo proessionally made, cabinet card (CC)mounted glossy collodion portraits were produced
rom the same negative but toned to produce images o different tonalities: violet black (fig. 12a)
and dark gray (fig. 12b). XRF analysis o the violet-black photograph reveals that it was heavily
toned using gold toner (fig. 13).
he XRF spectrum o the violet-black toned print shows the presence o silver (Ag) and gold
(Au) rom the image layer and barium (Ba) and strontium (Sr) rom the baryta layer. he
analytical signal o the other chemical elements detected by the XRF analysis o the Dmax area
o the photograph comes rom the mounting board o the photograph. he analysis o the back
o the mounting board conirms that these elements are present in the mounting board alone
(ig. 14).
XRF analysis o the dark-gray photograph (see fig. 12b) shows the presence o all the chemical
elements detected in the violet-black version, with the addition o platinum (Pt) (fig. 15). Tis,
together with gold toning, produces the dark-gray tonality. Te concentration o gold in this
image is substantially lower than in the violet-black photograph. Some experience is needed ininterpreting XRF spectra o photographs toned with both gold and platinum. Te spectral peak
o platinum (Pt L) at 9.44 keV overlaps with the spectral peak o gold (Au L) at 9.71 keV. Te
two XRF L spectral peaks or both elements also overlap (Pt L at 11.07 keV with Au L 11.44
keV). Tis overlap can be solved using an XRF spectrometer with a higher spectral resolution.
Figure 16 documents the spectral overlap o Au and Pt recorded using a combination o two thin
film standards o gold and platinum.
Figure 11 XRF spectrum of the unmounted, untoned glossy collodion photograph in fig. 5.
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Figure 12a CC-mounted glossy collodion photograph
with violet-black tonality.
Figure 13 XRF spectrum of the violet-black collodion photograph in fig. 12a, showing the use of gold toner.
Figure 12b CC-mounted glossy collodion photograph
with dark-gray tonali ty.
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Figure 14 XRF spectrum of the mounting board of the photograph in figure 12a.
Figure 15 XRF spectrum of the photography in fig. 12b, showing the presence of all chemical elements
found in fig. 12a, plus platinum (Pt).
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Tere is a strong overlap o both the Land L spectral peaks. For the small concentrations o
both elements, the resulting spectral peaks almost completely overlap, orming a broad double
spectral peak. Experience and the availability o analyzed samples with different concentrations
o both elements can help interpret the analytical data i an XRF instrument with higher spectral
resolution is not available.
FTIR
AR-FIR analysis is very effective when confirming the presence o collodion in the image
layer o the photograph or when detecting and identiying any application or treatment o glossy
collodion photographs with other types o organic coatings and varnishes. Tis method o
analysis also allows differentiation between unvarnished glossy, semi-matte, and matte-collodion
photographs. An example o a very glossy, nineteenth-century CC-mounted photograph appears
in figure 17a. AR-FIR analysis o this photograph (fig. 17b) shows all the typical spectral
attributes o glossy collodion photographs.
Te AR-FIR spectrum shows very intense and well-developed spectral peaks typical o
collodion (1630, 1270, and 821 cm1). Te presence o C-H bonds in the spectrum, 2917 cm1,
is typical or all organic materials with C-H bonds, but its relatively low intensity indicates theabsence o any varnish or organic coating. A typical glossy collodion image layer is very thin,
which allows the detection o a gelatin binder rom the baryta layer under the collodion layer.
A low-intensity Amide II spectral peak at about 1540 cm1usually indicates the presence o a
gelatin-based baryta layer.
Figure 16 Spectral overlap of Au and Pt using gold and platinum thin film standards, each containingapproximately 50 micrograms per square centimeter of the element.
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Figure 17a Nineteenth-
century CC-mounted
glossy collodion
photograph.
Figure 17b ATR-FTIR spectrum of the photograph in fig. 17a, showing typical spectral attributes of collodion.
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Post-Process Treatment of Glossy Collodion Photographs
Beore a matte variant o the collodion process was developed in the 1890s, the main procedure
used in creating a matte surace on glossy collodion photographs involved drying the photo on
a surace o matte glass or treating it with a beeswax-based varnish. Figure 18 shows an example
o such a photograph mounted on a CC substrate.
Te surace o the photograph is matte, with a slight sheen when viewed at an angle. Tephotograph does not exhibit the intererence color pattern typical o glossy collodion photographs.
No presence o surace coating is visible when examined under a microscope, but AR-FIR
analysis clearly detects the presence o the surace varnish layer (fig. 19).
Intense, well-developed spectral peaks o C-H unctional groups at 2956, 2916, and 2849 cm -1
indicate the presence o a varnish layer. Te presence o C-H vibrations o long aliphatic chains
(based on the ratio between CH, CH2, and CH
3peaks), together with the presence o the ester
unctional group at 1736 cm1, is typical or beeswax-based materials used in the nineteenth
century when treating or coating photographs and photographic negatives.
Figure 18 CC-mounted
glossy collodion
photograph treated with a
beeswax-based varnish to
produce a matte surface.
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IMPORTANT VARIANTS OF THE COLLODION PROCESS
Sel-toning collodion-on-paper photographs
Matte-collodion photographs
inted collodion photographs
Self-Toning Collodion-on-Paper Photographs
During the last quarter o the nineteenth century and the first decades o the twentieth century,
a number o sel-toning collodion papers became commercially available. Afer exposure and
development, these types o photographic papers produced toned photographs that today cannot
be easily distinguished rom photographs made using regular collodion photographic papers and
toned in the darkroom.
Matte-Collodion Photographs
A great number o proessional portrait photographers used different kinds o commercial matte-
collodion positive printing material rom its introduction in the 1890s to about the late 1920s,
when it was largely replaced by silver gelatin photographic material. Te matte-collodion process
was introduced to compete with, at that time, the highly popular platinotype photographic
process amous or producing beautiul matte-black or dark brown-black photographs. Even
Figure 19 ATR-FTIR spectrum of the collodion photograph in fig. 18, indicating the presence of the surface
varnish layer.
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today these photographs remain in a sound state o preservation without virtually any noticeable
color shif or discoloration.
Te matte surace o these photographs was produced by incorporating particles o starch into
the collodion-silver halide emulsion. Te standard darkroom treatment o matte-collodion
photographs called or double toning using both gold and platinum. A gold toner usually was
used first, and final tonality was achieved by a subsequent treatment in a platinum-toning bath.o achieve the desired tonality as shown in figures 20a20c required a certain level o darkroom
testing and calibration.
Figure 20a Matte-collodion photograph with dark-
brown tonality.
Figure 20c Matte-
collodion photograph with
bluish-black tonality.
Figure 20bMatte-collodion photograph
with dark brownish-black tonali ty.
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Figure 21a XRF spectrum of the dark-brown photograph in fig. 20a.
Figure 21b XRF spectrum of the dark brownish-black photograph in fig. 20b.
XRF analyses o these three photographs appear in figures 21a21c. A comparison o the spectra,
together with a larger number o other matte-collodion photographs analyzed during our research
project, shows no clear relationship between the final tonality o double-toned matte-collodion
photographs and the concentration ratio between gold and platinum in the photographs. Te
spectrum o the dark-brown photograph (see fig. 21a) has a low concentration o gold. Te two
very strong dark-black photographs show different chemical compositions. XRF analysis o
the dark brownish-black photograph (see fig. 21b) shows a high concentration o platinum andno gold. Te bluish-black photograph spectrum (see fig. 21c) shows a very high concentration o
gold and no platinum.
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Figure 21c XRF spectrum of the bluish-black photograph in fig. 20c.
Matte-collodion photographic papers were available commercially under different names. Te
American Aristotype Company, or example, produced the so-called Aristo-Platino printing
paper. A photograph produced using this paper is shown in figure 22a; a detail o the mount,
showing the photographers name and logo along with a description o the material used, is
shown in figure 22b. XRF analysis (fig. 23) shows that the photograph is a slight variant o a
regular gold- and platinum-toned matte-collodion photograph.
Figure 22aPhotograph made
using Aristo-Platino matte-collodion
photographic paper.
Figure 22b Detail of the mount for fig. 22a, indicating the
photographers name, logo, and description of material used.
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Tinted Collodion Photographs
Collodion photographs were usually not tinted, but some examples indicate the application o
colorants. Figure 24 shows two rare examples o untinted and tinted matte-collodion photographs.
XRF analysis shows that organic colorants were used in tinting the blue area (hat), red area (lips),
and white painted area o the photograph (fig. 25).
Figure 23 XRF spectrum of the Aristo-Platino photograph in fig. 22a.
Figure 24 Untinted
(left) and tinted versionsof a matte-collodion
photograph.
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Figure 26 XRF analysis of white paint used in the decoration of the photograph in fig. 25.
Only the dots o thick white paint indicate the presence o a very high concentration o zinc (Zn).
Te pigment used can be clearly identified as zinc oxide (fig. 26). Te concentration o organic
dye material is too low or AR-FIR identification o the individual dyes used or tinting o
the image.
Figure 25 Analytical
spots highlighting the use
of colorants in the blue
area (hat), red area (lips),
and white painted area
(collar).
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INTERPRETATIONG
UIDE
Table
1
Summaryofma
inmicroscopicandanalyticalsignaturesofcollodionphotographsandsome
processescommonlymisidentifiedas
collodion.
Theinformatio
nbelow
isfortypicalversionsofeach
process.
Exceptionstoeachentryma
yexistbutarerare.
Collod
ionPrints
Process
Surface
Coating
Paper
Fibers
Ag
Au
Pt
Ba
Other
Inorganics
Cellulose
Albumen
Collodion
Gelatin
Other
Organic
s
Surface/Tonality
Glossycollodion
X!
(X!)
(X)
X!
Sr!
X!
Brown
Mattecollodion
X!
(X!)
(X!)
X!
Sr!
X!
Black(mattesurface)
Wothlytype
(X)
X
X
U
X
X
Brown
Albumen
(X)
X
X
(X)
(X)
(Ti)*
X
X
(coatings)
Brown-purple
Gelatin
(X)
X
(X)
X
Sr,(Ti)*
X
(coatings)
Brown
Carbon
(X)**
(X)
Cr,(X)***
(X)**
X
Brown(glossy)
Woodburytype
(X)**
(X)
(Cr),
(Fe)
(X)**
X
Brown-black(shellac
inD-min)
X
Present
(X)**
CarbonandWoodburytypeprintsweresometimescoatedwithcollodion
Absent
(X)***
Rangeofcolorscanbeachieveddepen
dingonpigments/dyesused
()
Maybepresent
(Ti)*
Somemodernprintson20th-and21st-centurysubstratescontainingTiO
2
!
Keysignature
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