Today I ordered the first four books…a total of $90, including shipping. The last was given to me.
Mordants should never be handled with impunity; these should be used outdoors. Alums contain aluminum. And while aluminum is ubiquitous in our environment, exposure to it should be minimal. It is quite controversial that potassium aluminum sulfate (potassium alum) is often found in baking powder (not baking soda). Exposure to boiled aluminum mordants should not be carried on indoors. Additionally, aluminum sulfate alum produces sulphuric acid when mixed with water; you don’t want to be breathing this indoors.
To the end of mordanting fibre I bought an outdoor cooker yesterday – $85. It is just the burner, and is rated at 66,000 BTU. The flame is regulated by physically adjusting the air flow; this is done by physically turning a piece of aluminum (!) that covers a hole in the cast burner next to the input hose. It worked well on its initial burning; I can’t wait to try my first batch of fibre in it using both potassium alum and alum sulfate…
Seeing that the constituency of pots make an impact on the result of the dyes I decided to pull a couple of large aluminum pots out of storage, see how they do, and then to dedicate them to this in some fashion (we certainly didn’t want to use them in contact with any foodstuffs before this, or hereafter now either).
Salts are ionic compounds that result from the neutralization reaction of an acid and a base. Double salts are compounds obtained by combination of two different salts which were crystallized in the same regular ionic lattice. An example of a double salt is alum. Having an extra charged particle allows it to bind well with both the dye and the fibre to which the dye is being applied. This process of bonding in dyeing is commonly known as mordanting. Note that double salts should not be confused with a complex compound. When dissolved in water, a double salt completely dissociates into simple ions while complex compounds do not, the complex ion remaining unchanged in the later.
True alums have commonly been recognized as double salts of aluminum, such as potassium aluminum sulfate (left) – KAl(SO4)2.
Aluminum sulfate (right) – Al2(SO4)3 – is commonly known as an alum, although it is not a double salt. Aluminum sulfate is the result of the refining process of bauxite which is the raw state of aluminum ore. During this refining process sulfuric acid is used to remove most of the iron and silica present in bauxite.
The difference between these two may be subtle but may drastically show different dye results.Test the mordant with the dye you want to use. Study the Material Safety Data Sheet (MSDS) to determine if the aluminum sulfate you use has iron in it or is refined with potassium. Iron will also affect the dye’s outcome.
Additionally, the type of pot used in the dyeing process can also affect the dyeing outcome. Differences can happen whether you use stainless steel, aluminum, or iron pots during mordanting and dyeing.
Today I found a source of aluminum sulfate for less than a dollar a pound and reserved a 20 kg. bag with which to experiment in the coming weeks. Its MSDS will be telling. But even in the event of its containing iron it may have a use. Another common source for potassium alum is an Indian grocery store…look in the personal hygiene section for antiperspirant/antiseptic/aftershave bars – these are often made from potassium alum. Trying them as a mordant would be more than worth the effort.
…following up on the original dying I did with haskap, here is a comparison of washed fibre (right) against the original, unwashed fibre (left). i purposefully washed this patch with hot water and Tide detergent to see how badly this would damage the colour. It did remove the brilliance of the original red and turned it a brown-russet. Again, this is just a base-line washing with a table salt mordant….fyi…(again, full sun on snow)
Pic taken outside in full sun on snow…
Lot #4, mordanted (fixed) using NaCl (table salt) and not rinsed or washed (raw dyed llama fibre).
This post tells about my first dyeing of llama fibre using Lonicera caerulea (haskap) berries. The llama fibre is unwashed white from one of my own llamas, and the berries are from the Tundra selection of University of Saskatchewan haskap grown in my own orchard.
I set up this test using two sets of four samples:
- 1 – The first sample remained dry and undyed as a comparison.
- 2 – The second sample was dyed, but was not soaked or mordanted beforehand.
- 3 – The third sample was prepared by water soak preparation only.
- 4 – The fourth sample was prepared using a traditional salt mordant (NaCl).
Two samples were prepared from each. This will allow a comparison from each treatment before and after they dry and one is subsequently washed after several days in order to determine colour-fastness of this berry’s properties.
This procedure allowed me to compare later on as a base-line comparison of the simplest sort.
Haskap is a newly cultivated berry that found its way to North America in the 1990’s and is now being intensively bred and selected for at the University of Saskatchewan. Haskap is the name applied to a superior selection of genotypes of Lonicera caerulea. These plants are commonly known as edible blue honeysuckles, and also have been marketed using the name of Honeyberries. Their berries come from flowers that can withstand a -7C freeze and still produce fruit, and the plant is still viable after winter temperatures drop below -40C. It is truly a northern plant and modern plant origins can be traced to Siberia, the Kamchakta peninsula, and the northern island of Japan. The berry’s meat itself is coloured a deep, rich burgundy; it stains anything with which it comes into contact a bluish-purple. The stain can be removed by citric acid. Otherwise it is very difficult to remove. I can find no reference to its use as a cloth dye using a simple internet search. We currently have almost 3,000 plants in our orchard, parts of which are just now coming into full production.
- Since aluminum and iron can affect the the dying process (serving as mordants themselves), all utensils and pots used were made out of stainless steel.
- The salt mordant (fixative) consisted of 1/16 cup of salt to 1 cup of water (1/2 cup of salt to 8 cups of water for larger batches).
- The dye itself consisted of 1 cup of berries to 2 cups of water. This was brought to a boil, the berries crushed, the mix simmered for an hour with the lid on, and then strained.
- The third and fourth batches of fibre were simmered for an hour before being dyed. The third batch was simmered in water alone; the fourth batch was simmered in the salt mordant.
- All were then simmered in their own respective stainless steel pots with strained dye, again with devoted utensils.
- These were then set out to dry.
Tomorrow I will wash one piece of each lot and see if the dye remains fast or not. These will serve as a baseline for future dyeing, particularly in relationship to mordants such as alum (potassium aluminum sulfate KAl(SO4)2·12H2O).
Weaving begins with spinning, begins with carding, begins with cleaning, begins with shearing, begins with llamas, begins with hay…
Not all llama fibre is the same. In particular when it comes to guard hair, some individuals are guard hair free, while others’ fibre is heavily laden with it. It is thought that the purpose of guard hair is to serve as a wick that draws water away from the insulating value of the animal’s fibre. This is helpful for animals living in the wild, whereas people domestically breeding for fibre will select for individuals without guard hair. Some of my animals have no guard hair (above). Some have a lot of guard hair (below).
I have raised llamas for twenty years. But I select animals based upon their tractability as pack animals.
The greatest advantage of llama fibre for me is that it is available. I have 20 years of it dried and stored. Looking into having it processed these days is ridiculous, cost-wise. I believe that I will buy an electric carder, and try and figure out how to get it spun. But in due time..