Version 'S'
Chemicals Required for the Sensitizer
A. 3,3'-Thiodipropanoic acid (aka 3-3'-Thiodipropionic
acid)
B. either B1. Sodium tetrachloroaurate(III) dihydrate
or B2. Hydrogen tetrachloroaurate(III) trihydrate
C. Ammonium iron(III) oxalate trihydrate
D. either D1. Sodium carbonate (anhydrous)
or D2. Sodium hydrogen carbonate
E. Tween 20
F. Water (pure)
Chemicals Required for Processing
Developing agents;one or more of the following:
Disodium Edta(1,2-Diaminoethanetetraacetic acid, disodium
salt)
Citric acid
Tartaric acid
Oxalic acid
Clearing agents:
Tetrasodium Edta (1,2-Diaminoethanetetraacetic acid, tetrasodium
salt)
Sodium sulphite or sodium metabisulphite or Kodak
Hypo Clearing Agent
Apparatus Required for Making up the Sensitizer
One small Pyrex or Corning glass beaker (100-200 cc)
One graduated glass measuring cylinder (50-100 cc)
One large beaker or plastic measuring cylinder (ca. 500 cc)
One small conical filter funnel (ca. 5-6 cm diameter)
Filter papers: Whatman Grade #1, (ca. 8-10 cm diameter)
Two glass stirring rods, one long and one short.
Dropping pipette (2-3 cc capacity) or small graduated syringe
Balance or scales accurate to ± 0.1 g
Electric hotplate/magnetic stirrer (or, simply a basin of hot water)
Spatula or small plastic spoon
Washbottle filled with pure water
Three brown glass bottles with plastic screw-caps, ca. 50 cc capacity
Self-adhesive labels and indelible pen
Preparing Stock Solutions for Version 'S' Sensitizer
A. Ligand solution (1.4 molar)
- Weigh out 12.5 g of 3,3´-thiodipropanoic acid and transfer it
into a beaker or measuring cylinder of ca. 500 cc capacity (This vessel
is necessarily large in order to contain the foam generated in the reaction
that follows).
- Weigh out separately 7.4 g of sodium carbonate (anhydrous powder),
or 11.8 g of sodium hydrogen carbonate.
- Add ca. 30 cc of pure water to the thiodipropanoic acid and stir it
into a suspension with a glass rod.
- Slowly add the solid sodium (hydrogen) carbonate powder, in small
portions of ca. 1 g, to the suspension of thiodipropanoic acid. There will
be effervescence as carbon dioxide gas is evolved - this is harmless. The
suspension will foam up alarmingly, but it should be contained by the tall
vessel. Stir well and allow the foam to subside between additions. The solution
becomes cold, so may be slightly warmed in a bath of hot water to hasten
the reaction. Continue until there is no further effervescence, leaving
a colourless solution. A few residual solid particles do not matter.
- Pour the solution into a small measuring cylinder (50-100 cc capacity)
and make it up to a final volume of 50 cc with pure water from the wash
bottle and mix well.
- Filter the solution through a #1 filter paper directly into the stock
bottle (this is a slow process because the solution is somewhat syrupy.)
This solution should keep indefinitely, if correctly made up. Label it with
the date and the following:
New Chrysotype: Version 'S'
Solution A: Ligand
Disodium thiodipropanoate 1.4 molar
B. Gold solution (0.35 molar)
either B1
- Carefully transfer or weigh out 5.0 g of sodium tetrachloroaurate(III)
into a Pyrex glass beaker of 100 cc capacity. Use a plastic spatula or spoon
- this gold salt will attack stainless steel and nickel.
- Add ca. 25 cc of pure water at room temperature to the gold salt in
the beaker. You should use some of this water to wash out and transfer any
residual crystals of gold salt from your weighing bottle or vial, by means
of a dropping pipette. With gentle agitation, all the solid will easily
dissolve to a yellow solution at room temperature.
- Filter the solution carefully into a measuring cylinder (50-100 cc
capacity) using a small conical filter funnel and a Whatman #1 filter paper,
or equivalent.
- Add pure water from the washbottle, a little at a time, to the filter-paper,
allowing it to pass through to wash out most of the residual yellow solution,
and to make up the final volume to exactly 36 cc in the measuring cylinder.
Mix thoroughly.
- Transfer the solution carefully from the measuring cylinder to the
stock bottle. This solution is stable indefinitely. Label it with the date
and the following:
New Chrysotype: Version 'S'
Solution B: Gold
Sodium tetrachloroaurate 0.35 molar
or B2
If hydrogen tetrachloroaurate(III) is cheaper or more readily available
than the sodium salt, then you can make your gold solution from it, using
the following procedure for neutralizing this acid with anhydrous sodium
carbonate or sodium hydrogen carbonate:
- Carefully transfer or weigh out 5 g of hydrogen tetrachloroaurate(III)
into a tall measuring cylinder (100 cc capacity). Use a plastic spatula
or spoon - this gold salt attacks steel and nickel.
- Add ca. 30 cc of pure water at room temperature to the measuring cylinder.
You should use some of this water to wash out and transfer any residual
crystals of gold salt from your weighing bottle or vial, by means of a dropping
pipette. With gentle agitation, all the solid will easily dissolve to a
yellow solution at room temperature.
- Weigh out (precisely, if possible) 0.673 g of sodium carbonate (anhydrous
powder), or 1.07 g of sodium hydrogen carbonate, using a chemical
balance. If your balance is not this precise, the figures may be rounded
up to 0.7 g or 1.1 g respectively.
- Slowly add the sodium (hydrogen) carbonate in small portions (tip
of a spatula), to the solution of chloroauric acid. There will be vigorous
effervescence as carbon dioxide gas is evolved. The spray should be contained
by the tall measuring cylinder. Swirl the solution, and continue adding
the solid to completion and no further effervescence.
- Add pure water from the washbottle to make up to a final volume of
exactly 36 cc in the measuring cylinder with thorough mixing.
- Filter the solution carefully into the stock bottle through a small
#1 filter paper to minimise the residual loss of solution. Label it:
New Chrysotype: Version 'S'
Solution B: Gold
Sodium tetrachloroaurate 0.35 molar
C. Iron solution (1.4 molar)
The following procedure must be carried out under subdued indoor
lighting, not in daylight (a 60 watt incandescent tungsten bulb at least
1.5 meters away).
- Weigh 30 g of ammonium iron(III) oxalate into a small Pyrex glass
beaker of ca. 100 cc capacity.
- Add exactly 33 cc of pure water (from a measuring cylinder) at room
temperature to the salt in the beaker. Stir well with a small glass rod
to dissolve the bulk of the solid. The solution becomes cold, so gently
warm the beaker in a bath of hot water to assist dissolution.
- Within 5 minutes the solid will have dissolved to form an emerald-green
solution (any slight cloudiness from a few remaining fine crystals of impurity
should be ignored). The solution does not need to be 'made up', because
its total volume should already be correct = 50 cc.
- Filter the solution through a Whatman #1 paper in a conical funnel,
directly into a clean, dry brown bottle.
- Store this bottle in the dark at room temperature. If, after a few
days, a few white needle-like crystals (probably of ammonium oxalate) have
appeared, re-filter the solution to remove them. This solution is close
to saturation, and if it is allowed to cool much below 20 °C (68 °F),
some emerald-green crystals may slowly grow at the bottom of the bottle.
Warm gently and swirl to re-dissolve these. Stored carefully at room temperature
in the absence of light, this solution will keep indefinitely. Label it
with the date and the following
New Chrysotype: all Versions
Solution C: Iron
Ammonium iron(III) oxalate 1.4 molar
Mixing the Sensitizer Solution for Version 'S'
The primary control of contrast in this process is provided by the molar
ratio of ligand : gold, which can be varied between 2 and 6. A 'standard'
value of 4 is recommended for your first trials. The molar ratio of gold
: iron is always 1. Given the concentrations of the solutions made up as
above (the ligand and iron solutions have the same concentration, 1.4 molar,
which is 4 times the concentration of the gold solution, 0.35 molar), this
determines that the volume ratios for these three solutions,
A : B : C to mix a 'standard' sensitizer must be:
Volume Ratios of Ligand : Gold : Iron = A : B : C = 4 : 4 :
1
However, these volume ratios can be varied between the limits:
A : B : C = 2 : 4 : 1 and 6 : 4 : 1
in order to vary the contrast. (Note that the first of these ratio
numbers also tells you, conveniently, the molar ratio of ligand to gold).
The values you prefer will be decided by your personal taste and the density
ranges of your negatives, but here are some guidelines:
Lower ligand : gold ratios than the 'standard' value of 4 give less stable
sensitizers, which will print faster, with a longer tonal range and higher
maximum density, but they have a greater tendency to fog in the highlights
and to decompose before coating.
Higher ligand : gold ratios than the 'standard' value of 4 give more stable
sensitizers, which will print less rapidly, showing higher contrast and
slightly lower maximum densities, with clean highlights.
There is no benefit in significantly increasing the proportion of iron (C)
in the ratios, because this tends to cause 'blocking up' of tonal gradation
in the shadows, 'bleeding' of gold pigment from overexposed regions, and
lower maximum densities. However, a small excess of iron (C) will
do no harm.
The actual volumes of the solutions you need to measure out will, of course, depend
on the total area to be coated, i.e. number and size of your coatings, the nature
of your paper, and the ligand : gold molar ratio you have chosen. As a guide,
typical figures are set out in Table 1 for making up 10 cc of mixed sensitizer.
Table 1. Component solution volumes to make 10 cc of chrysotype sensitizer.
Ligand:Gold
Molar Ratio
|
Volume of A
Ligand(1.4M) |
Volume of B
Gold(0.35M) |
Volume of C
Iron(1.4M) |
| 2 |
2.86 cc |
5.71 cc |
1.43 cc |
| 2.5 |
3.33 |
5.33 |
1.34 |
| 3 |
3.75 |
5.00 |
1.25 |
| 4 (standard) |
4.44 |
4.44 |
1.12 |
| 5 |
5.00 |
4.00 |
1.00 |
| 6 |
5.45 |
3.64 |
0.91 |
This is sufficient to coat about eight 10.25" x 8.25" (260 x 210 mm)
areas of paper, on the assumption that each sheet requires ca. 1.25 cc of sensitizer
solution (which is true for Fabriano 5, HP 210 gsm paper). For total volumes other
than the 10 cc used in this illustration, you should scale these numbers accordingly,
selecting the row of volume figures, A, B, C that corresponds with your
chosen ligand : gold molar ratio. For example, if you find that your chosen paper
requires 1.6 cc for each coating, and you wish to coat 8 sheets, then you will
require 8 x 1.6 = 12.8 cc of sensitizer, so each figure in the appropriate row
should be multiplied by 1.28 to give the volumes to be measured out. These small
volumes are conveniently and accurately measured out with the small graduated
syringes, of capacity 1, 2, and 5 cc. It is good practice to dedicate a particular
syringe to each solution, with an identifying mark, to avoid cross-contamination.
The solutions must be mixed in the following sequence:
- Deliver the volume A of ligand solution into the mixing
vessel using a graduated syringe.
- Add the volume B of gold solution, drop by drop, from
another syringe, with stirring or, preferably, careful swirling of the vessel
(which avoids introducing a stirring rod). Allow time between each drop
(1-2 seconds) for the gold solution to decolorise.
- When step 2 is complete, add the volume C of iron solution,
from a third syringe, to give a pale yellowish-green sensitizer.
- Mix thoroughly and, using a fourth syringe, coat the paper sheets
in the way described in the Preparations article.
Although these volume figures have been quoted rather precisely, do not
be daunted if you find it difficult to achieve this degree of accuracy in
measurement: even with a calibrated syringe, you may have to guess the second
decimal place. The process is quite forgiving over a range of values and
you will obtain a result, albeit less predictable, with almost any reasonable
combination of volumes.
The stability of the made-up sensitizer solution depends on the ligand :
gold molar ratio and the temperature, but all solutions should last for
at least 30 minutes at 20 °C without showing any perceptible decomposition,
which is sufficient time to coat a batch of sheets. The mixed solution cannot
be stored; although the 'standard' solution should last at least 2 hours.
Decomposition is indicated by the deposition of metallic gold, which plates
the container.
Coating and Drying
The method of coating the paper has been described fully in Preparations.
If difficulty is encountered in achieving an even coating, a little Tween
20 may be added to the sensitizer to improve the absorption of the sensitizer
by the paper fibres: 0.1-0.3 cc of a 20% v/v solution, per 10 cc of sensitizer
solution, is appropriate (i.e. a final Tween concentration in the sensitizer
of 0.2 to 0.6%). Tween may also assist in 'smoothing out' the tones if a
grainy or fibrous image is obtained, but tends to be incompatible with gelatin-sized
papers.
Immediately following the coating, allow the sheet to rest horizontally
for a few minutes so that the sensitizer can soak into the surface fibres,
as indicated by the disappearance of the reflective sheen. It may then be
dried in a uniform stream of warm (40 °C) air for about 10 minutes.
After heat-drying, the coated paper may be stored in a light-tight desiccator
at a Relative Humidity (RH) of 10% or less. The lifetime of prepared paper
in storage is variable, depending on the parameters of the sensitizer. For
preference, to avoid introducing this uncertainty, the paper should be exposed
and processed on the same day that it is coated. If you adopt this as your
method of working, then heat-drying the coating is not essential (unless
you desire the result of a low RH): just leave it in the dark, e.g. in a
drawer with plenty of air circulation to the environment, at room temperature
for an hour or so, which suffices to reach equilibrium with the ambient
RH.
Regulating the Humidity of the Paper
To attain a predictable result for the colour of the image, the water content
of the sensitized paper must be controlled before exposure. Varying degrees
of hydration will produce different colours in the print and different extents
of printout: high RH generally yields a nearly complete printout in fairly
neutral grey tones, or with a hint of blue or green. The lowest RH values
give almost no printout: only the shadow tones are faintly visible, and
the image is generated almost entirely by development, with pinkish-brown
or dull red shadows and greyish-blue high values. The intermediate values
of RH can provide strongly split-toned scales, with purple and magenta shadows
graduating into blue highlights. This results from partial printout coupled
with a some degree of development. Hydration can be controlled in two different
ways, which will now be described. The first is simpler, but requires more
attention because the process must be timed.
Water hydration chamber (time-dependent method)
A heat-dried paper may be humidified over pure water, at 100% RH, for a
timed period of up to 30 minutes, as described in Preparations. If the ambient
temperature is much different from 20 °C, then some correction to the
time is necessary for consistent results.
Salt hydration chambers (equilibrium method)
These are chambers of known, constant RH, provided by saturated solutions of specified
salts. Details of the construction and use of such enclosures has been described
in Preparations. It is unnecessary to have a full range of RH chambers, however,
and initially I recommend that you prepare just three, using the substances in
Table 2, which will convey some idea of the range of colour behaviour. Following
that, the use of other RH values will be a matter of exploration and personal
taste.
Table 2. Salts for the control of Relative Humidity atmospheres.
| No. Substance |
Formula |
RH% |
| H1 Calcium chloride anhydrous |
CaCl2 |
9 |
| H4 Calcium chloride sat. aqueous |
CaCl2 |
45 |
| H7 Sodium chloride sat. aqueous |
NaCl |
75 |
| or |
|
|
| H8 Ammonium chloride sat.aqueous |
NH4Cl |
80 |
The RH box H1 can also be used for the storage of coated paper. Paper should
be heat-dried before placing in this box, so as not to exhaust the desiccant
too quickly. The RH box H4 can be made up using the spent calcium chloride
from an H1 box, when it becomes too moist. A saturated solution is prepared,
in contact with excess solid, in each case, as described in Preparations.
Hydration in these chambers requires a minimum of half an hour, but papers
may be left longer. The paper may tend to fog in the higher RH baths if
it is left for much more than an hour, but if you intend to equilibrate
at high RH, H7 or H8, the initial drying in hot air is unnecessary.
Exposure
Exposure times vary somewhat with the ligand : gold molar ratio, but are
generally as short as for palladium sensitizers, for example. Using even
modest UV light sources, adequate exposures may only be one or two minutes.
The extent of printout is nearly total at high RH values, leaving less than
1 stop of development, but the printout decreases in the dried sensitizers,
leaving 4 to 6 stops of development at the lower RH values. Test strips
or step tablet tests are a useful guide in the latter case. The negative
density range appropriate for a full tonal range in the print is indicated
in Table 3 below, under 'controlling the contrast'. However, 'softer' negatives
can still yield effective prints, especially if a high ligand : gold ratio
is used.
Making up the Processing Solutions
Recommended Developer
Disodium Edta, ca. 1% w/v solution: dissolve ca. 10 g (one rounded 5 cc
teaspoonful) in 1 litre of tap water at room temperature. Use this for a
few prints only, in one session. Do not store it. When it acquires the colour
of colloidal gold it is liable to stain subsequent prints, and should be
replaced. Do not use tetrasodium Edta, which is alkaline, and will cause
iron stains.
Alternative Developers
Any of the following can be made up and used as 1-2% w/v solutions: tartaric
acid; citric acid; oxalic acid. Because they are acids, overlong treatment
may tend to block up the shadow tones, due to the coagulation of the gold,
and better results may be obtained by using their sodium, potassium or ammonium
salts.
These 'developers' should ideally all be employed as 'one-shot' process
baths, or nearly so. Practically speaking, a 1 litre bath should be sufficient
for 2 or 3 prints 10" x 8" or the equivalent area of smaller prints.
It is risky to re-use these 'first bath' solutions, because they acccumulate
most of the excess iron and gold salts, and soon acquire the ruby-red colour
of colloidal gold which may cause staining of subsequent prints. Do not
store these solutions: make them up, ca. 1-2% in strength, as needed, by
dissolving a rounded teaspoonful (8 cc) of the solid in one litre of water
at 20 °C.
Clearing Baths #I and #III
Tetrasodium Edta, ca. 5% w/v solution: dissolve 50 g in 1 litre of tap water
at room temperature. Two such clearing baths are required. They may be stored,
and will have a capacity of around 50 10" x 8" prints per litre.
It is economical to use '2-bath fixing procedure', by replacing the #I bath
by the #III bath, when it is exhausted.
Clearing Bath #II
Sodium sulphite, sodium metabisulphite, or Kodak Hypo Clearing Agent: ca.
2.5% w/v: dissolve ca 25 g (1 level 15 cc tablespoonful of solid) in 1 litre
of tap water at room temperature. This bath should not be stored, but made
up fresh from solid for one day's printing.
Processing of the Exposed Print
- Post-hydrate.
This is an optional step in which the print is humidified, after
exposure but before wet processing, by placing it in a water hydration
chamber for a period of 2 to 15 minutes. The print is held parallel to and
above, but out of contact with, the surface of water (larger than the print
in extent). If the water is warmed to ca. 40 °C the processing time
can be shortened to 1-2 minutes, and the degree of development will be very
complete. (A photographic dish-warmer serves well for this purpose. The
arrangement is essentially the same as that for humidifier enclosures; for
details see Preparations.) If you desire the lowest contrast, with the longest
possible tonal scale, and the most delicate high values, then this procedure
is strongly recommended. It allows the image to develop almost completely
before it is immersed in the wet baths, which immediately start to
wash out the chemicals. The hues are generally fairly monochromatic, i.e.
without strong 'split tones', because of the lack of development. Post-hydration
also yields very smooth tones. However, prolonged post-hydration can lead
to chemical fogging of the image. Uniformity in exposure to the water vapour
is important, and the humidifying tank should be kept in a draught-free
location.
- Develop.
One of the following 'developers' may be chosen, although 'development'
is something of a misnomer here for the higher RH values, because the chief
action of these baths is as 'clearing' agents. However, each does have a
slightly different effect in 'fine-tuning' the resultant colour of the gold
image. Vigorous agitation is important for the first couple of minutes.
Prints may remain in this bath for up to 10 minutes.
Water: this is the least 'energetic' option, and gives the greatest
apparent contrast, because the high values may be truncated by lack of any
developing agent.
Disodium Edta; 5-10 minutes gives a clean result with fairly neutral
tones.
Tartaric acid; yields redder tones, but still fairly subdued.
Citric acid; from 1 to 6 minutes can produce a long tonal range of
rose-pink hues crossing over into blue highlight tones if the sensitizer
was exposed at low RH values. The intensity of the red colour in the shadows
increases progressively with time and intensifies in the clearing baths.
Overlong treatment may cause 'blocking up' of the shadows and a loss of
tonal separation when the print dries down.
Oxalic acid; causes the most intense and striking red/blue colour
splits and the longest tonal range.
These are not the only possibilities - the list of reagents could be very
long - and opportunities for experiment are endless. The main criteria for
selecting a chemical for the 'first bath' are: it should be a non-alkaline,
non-reducing, chelating or complexing agent for ferric iron.
- Rinse.
To avoid carry-over of chemicals to the next bath, the print should be briefly
washed for half a minute in gently running water.
- Clear #I.
10 minutes in a bath of 5% w/v tetrasodium Edta, with only occasional agitation
needed. Red tones will tend to intensify in this bath.
- Rinse.
briefly for a few seconds.
- Clear #II.
10 minutes in a freshly-made bath of sodium sulphite or metabisulphite or
Kodak Hypoclearing Agent of concentration ca. 2.5% w/v. Very little is agitation
needed.
- Rinse.
briefly for a few seconds.
- Clear #III.
10 minutes in a second bath of 5% tetrasodium Edta.
- Wash.
30-60 minutes in gently running water.
- Dry.
Drain, face outwards, on a near-vertical sheet of glass, or Perspex (Plexiglass
in the USA), and then peg up on a line to air-dry, or place on a horizontal
drying screen. Alternatively, if cockling of the paper sheet is a problem,
blot or roller it, and allow it to dry between sheets of high quality blotting
paper, such as Multisorb, preferably under some pressure.
Summary of the Steps in the New Chrysotype Process
- Pre-hydrate paper [only if RH < 50%]
- Mark up for coating with template, and number the paper
- Dust down paper and clip or tape up for coating
- Mix sensitizer [A:B:C = 4:4:1 standard]
- Coat paper [5 passes standard] & blot off excess
- Rest paper horizontally till sheen goes
- Dry in warm air stream [40 ºC] 10 mins
- Store in CaCl2 [9% RH] if not immediately required
- Hydrate @100% RH @ 20 ºC for timed period or use constant humidity
box
- Register with negative in print frame
- Expose to UVA light source 1 to 10 mins
- Post-Hydrate @100% RH @ 20 ºC, 5 to 15 mins, or @ 45 °C
1-2 mins
- Develop in disodium Edta [1%] or other,10 mins
- Rinse in running water
- Clear #I in tetrasodium Edta [5%] 10 mins
- Rinse
- Clear #II in sodium sulphite or KHCA, 10 mins
- Rinse
- Clear #III in tetrasodium Edta [5%] 10 mins
- Wash in running water 30 mins
- Drain on vertical Plexiglass sheet 15 mins
- Dry in air at room temperature and RH
Controlling the Contrast
The contrast of the sensitizer is defined by its printing exposure range,
which is conveniently expressed as the negative density range, D, to produce
tones from print highlight to deepest shadow. Control of this is achieved,
as indicated earlier, by varying the molar ratio of ligand to gold, through
the volumes and concentrations of the solutions A : B. A minimum
value of molar ratio 2 gives the longest range of tones; however this ratio
also corresponds to a very 'fast' and unstable sensitizer which tends to
suffer fogging of the highlights. As the molar ratio is raised, the contrast
increases as indicated approximately in Table 3 below; the performance also
becomes more predictable; the clearing of the highlights is cleaner and
the exposure times will require lengthening.
Table 3. Dependence of sensitizer contrast on ligand : gold molar ratio.
| Ligand:Gold molar ratio: |
2 |
2.5 |
3 |
4 |
5 |
6 |
| Print exposure range, D: |
2.8 |
2.4 |
2.2 |
2.0 |
1.8 |
1.6 |
Controlling the Colour
The colour of a new chrysotype print depends on four main factors: the Version
of the chemistry; the humidity of the coating during exposure; the sizing
agent in the paper; and the developer used in the wet-processing procedure.
In addition, the result also depends on the acidity of the sensitizer: a
more acidic sensitizer produces darker and duller reds with less printout.
Hydration of the coating prior to exposure
The primary control of colour is the RH of the coated paper's environment
before exposure. At low values (ca. 10%), the colours are predominantly
pink and reddish-brown. As the RH is raised, the dominant colour shifts
through magenta, via purple (45%), to bluish-black (80%). At high RH a fine
range of grey/black tones is obtained, which compares very favourably with
the best that the platinotype process can achieve.
Effect of the sizing agent
To obtain the best red and pink colours, choose a paper that has been tub-sized
with gelatine, e.g. Fabriano 5, Arches Aquarelle, T.H. Saunders 'Waterford',
or Ruscombe Mill's 'Talbot' paper. Alternatively you can surface-size papers
yourself with gelatin as described in Preparations. Gelatin tends to stabilise
and 'protect' the smallest particles of colloidal gold, which appear red.
For more neutral blue-black tones and dull magentas, the papers internally
sized only with Aquapel may be used - especially Ruscombe Mill's 'Buxton'
paper.
Choice of developing agent
The choice of 'developer' also influences the final colour, as outlined
above: ranging from water through to oxalic acid. These developers act differently
in conjunction with the RH. At low RH, citric acid produces pinks, and disodium
Edta browns, however at high RH citric acid produces bluish, and disodium
Edta greenish, results.
Full instructions on all aspects of chrysotype printing are contained in my 211 page book The Chrysotype Manual obtainable from the Siderotype website.
A set of Instructional Workshop Notes for the New Chrysotype process may be downloaded here.