Floating Clay - Ceramic Arts Daily
Floating Clay - Ceramic Arts Daily Floating Clay - Ceramic Arts Daily
to use slabs again, but make a five-sided “cap” that would be inverted on the surface of the water and trap air underneath. For insurance, I could float the cap with buoyant materials like foam blocks or inflated inner tubes: not an elegant or enduring solution. I might have tried it, and it might have worked, had I not heard the legend of the mysterious floating clay. In Japan, the government supports their ceramists to such a degree that it builds and operates glaze- and clay-testing facilities in each prefecture. According to the story, back in the 1960s, government ceramics scientists were experimenting with various additives for clay and accidentally discovered that it was possible to make clay float. Recently, a scientist at the Shigaraki facility had reopened the file on this baffling paradox and had been performing experiments in the hope of finding a viable commercial application. A minuscule amount of silicon carbide is added to a uniquely composed clay body. The silicon carbide turns into a gas during the firing, which is encapsulated within the clay in the form of bubbles. Each bubble is completely sealed so the gas can’t escape and no water can permeate the clay. The final product is confounding. It is deceptively light and has a waferlike consistency. It is lighter than soft kiln brick or pumice. When cut or broken, the interior reveals the gaseous bubbles and looks like baked bread. Alas, floating clay is challenging to work with. Even with adding methyl cellulose and toilet-paper pulp, the clay body is short and has very little elasticity. Despite this drawback, it is not necessary to slip and score when working with floating clay, as the parts will fuse together while firing. You can make fairly thick objects as well. If the silicon carbide is not evenly mixed into the clay, uneven distortion can occur. If the clay is well mixed, the final product will “rise” in the kiln and expand in a uniform fashion, but it is not particularly strong or resistant to wear. On the other hand, it doesn’t retain heat, it won’t crack when frozen and it floats on water! Mixing Floating Clay One of the greatest challenges I encountered was in getting the active ingredient, silicon carbide (SiC), evenly distributed through- The Shigaraki Ceramic Cultural Park provides space for artists, as well as research and exhibition facilities. Ceramics Monthly February 2004 59 out the clay body. This is partly due to the fact that the SiC comprises only 0.5% of the total dry weight of the clay body. I mixed the clay by first mixing all dry ingredients together, minus the SiC. Then I took 10% of the dry-mixed ingredients and added the SiC. This was shaken vigorously in a plastic bag for a few minutes, then ball milled for approximately 20 minutes. Next, I added more dry ingredients (about 40% total weight) and placed that in a dough mixer for 20 minutes. Because the clay is composed of 25% water, I added all of the water to only 40% of the dry ingredients, made a slurry in the dough mixer and let it mix for 10 minutes. I then added in the remaining dry ingredients and mixed thoroughly. Forming Because of the absurdly high feldspar content, Floating Clay is very short. It has almost no elasticity and is difficult to dry without cracking. I remedied this problem somewhat by adding one or more of the following ingredients: methyl cellulose (a weak, nontoxic adhesive), Biopoly (an organic additive), and toilet-paper pulp for strength (one roll of toilet paper for every 10 kilograms of wet clay). Floating Clay can be thrown, but the forms I threw slumped a lot in the kiln. Perhaps decreasing the silicon carbide, or firing to a slightly cooler temperature, might have helped. Give it a try! PHOTOS: SHINJI OTANI
Finished sculptures made of colored Floating Clay, fired to Cone 8, by Randolph Sill, Seattle, Washington. Firing This is important. Protect your kiln in the following two ways: First, recognize that floating clay distorts and expands in the kiln. Leave a lot of extra space around your pieces. I can’t tell you how much they will rise, as that depends on the total quantity of clay that is fired. For example, a 6-inch-diameter, 1-inch-tall cookie may only grow to be 7 inches in diameter. A 6-inch-diameter, 4-inch-tall cookie may end up growing to 9 inches in diameter. Second, coat the kiln shelves with a thick layer of alumina hydrate in powder form as well as kiln wash. Sift it right onto the shelf. It should be about ⅛ inch thick. This will not only prevent the clay from sticking to the shelves, it will allow the clay to grow horizontally with as little friction against the kiln shelf as possible. Don’t skimp on the alumina hydrate, as you can reuse it in subsequent firings. If you have any breakthrough discoveries, or if you need more recipes or information, please contact Randolph Sill through www.madpotter.com. Ceramics Monthly February 2004 60 recipes White Floating Clay Base (Cone 8) Hata Feldspar .................................. 80.0 % Motoyama Clay ............................... 10.0 New Zealand Kaolin ........................ 10.0 100.0 % Add: Methyl Cellulose ..................... 1.0% Silicon Carbide ........................ 0.5 % This base recipe has low distortion, but is less buoyant than the pink base. Pink Floating Clay Base (Cone 8) Hata Feldspar .................................. 50.0 % Nissan Feldspar ............................... 30.0 Bentonite ........................................ 5.0 Motoyama Clay ............................... 10.0 New Zealand Kaolin ........................ 5.0 100.0 % Add: Methyl Cellulose ..................... 1.0% Silicon Carbide ........................ 0.5 % The pink color of this base is a bit muted. It has more distortion upon firing and, as a result, is more buoyant than the white base. Substitutions for Motoyama clay should contain less than 20% sand. Colorants for Floating Clay Royal Blue Cobalt Oxide ....................... 0.5–1.0 % Brilliant Blue Blue Mason Stain ...................... 3.0% Bright Yellow Vanadium Oxide ....................... 3.0% Light Green Vanadium Oxide ....................... 3.0% Chrome Oxide .......................... 0.5% Dark Green Chrome Oxide .................... 0.5–1.0 % Mint Green Copper Carbonate .................... 1.0% Percentages based on weight of wet clay. Other colors can be tested using stains at 3% as a starting point. Hata Feldspar K2O ................................................... 30% Na2O ................................................. 50 SiO2 ................................................... 20 100 % Nissan 7 Feldspar K2O ................................................... 30% Na2O ................................................. 30 SiO2 ................................................... 39 Fe O ................................................. 1 2 3 100 %
to use slabs again, but make a five-sided<br />
“cap” that would be inverted on the surface<br />
of the water and trap air underneath. For<br />
insurance, I could float the cap with buoyant<br />
materials like foam blocks or inflated<br />
inner tubes: not an elegant or enduring<br />
solution. I might have tried it, and it might<br />
have worked, had I not heard the legend of<br />
the mysterious floating clay.<br />
In Japan, the government supports their<br />
ceramists to such a degree that it builds and<br />
operates glaze- and clay-testing facilities in<br />
each prefecture. According to the story, back<br />
in the 1960s, government ceramics scientists<br />
were experimenting with various additives<br />
for clay and accidentally discovered<br />
that it was possible to make clay float. Recently,<br />
a scientist at the Shigaraki facility<br />
had reopened the file on this baffling paradox<br />
and had been performing experiments<br />
in the hope of finding a viable commercial<br />
application. A minuscule amount of silicon carbide is added to a<br />
uniquely composed clay body. The silicon carbide turns into a gas<br />
during the firing, which is encapsulated within the clay in the<br />
form of bubbles. Each bubble is completely sealed so the gas can’t<br />
escape and no water can permeate the clay.<br />
The final product is confounding. It is deceptively light and<br />
has a waferlike consistency. It is lighter than soft kiln brick or<br />
pumice. When cut or broken, the interior reveals the gaseous<br />
bubbles and looks like baked bread.<br />
Alas, floating clay is challenging to work with. Even with<br />
adding methyl cellulose and toilet-paper pulp, the clay body is<br />
short and has very little elasticity. Despite this drawback, it is not<br />
necessary to slip and score when working with floating clay, as the<br />
parts will fuse together while firing. You can make fairly thick<br />
objects as well. If the silicon carbide is not evenly mixed into the<br />
clay, uneven distortion can occur. If the clay is well mixed, the<br />
final product will “rise” in the kiln and expand in a uniform<br />
fashion, but it is not particularly strong or resistant to wear. On<br />
the other hand, it doesn’t retain heat, it won’t crack when frozen<br />
and it floats on water!<br />
Mixing <strong>Floating</strong> <strong>Clay</strong><br />
One of the greatest challenges I encountered was in getting the<br />
active ingredient, silicon carbide (SiC), evenly distributed through-<br />
The Shigaraki <strong>Ceramic</strong> Cultural Park provides space for artists, as well as research and exhibition facilities.<br />
<strong>Ceramic</strong>s Monthly February 2004<br />
59<br />
out the clay body. This is partly due to the fact that the SiC<br />
comprises only 0.5% of the total dry weight of the clay body. I<br />
mixed the clay by first mixing all dry ingredients together, minus<br />
the SiC. Then I took 10% of the dry-mixed ingredients and<br />
added the SiC. This was shaken vigorously in a plastic bag for a<br />
few minutes, then ball milled for approximately 20 minutes.<br />
Next, I added more dry ingredients (about 40% total weight) and<br />
placed that in a dough mixer for 20 minutes. Because the clay is<br />
composed of 25% water, I added all of the water to only 40% of<br />
the dry ingredients, made a slurry in the dough mixer and let it<br />
mix for 10 minutes. I then added in the remaining dry ingredients<br />
and mixed thoroughly.<br />
Forming<br />
Because of the absurdly high feldspar content, <strong>Floating</strong> <strong>Clay</strong> is<br />
very short. It has almost no elasticity and is difficult to dry<br />
without cracking. I remedied this problem somewhat by adding<br />
one or more of the following ingredients: methyl cellulose (a<br />
weak, nontoxic adhesive), Biopoly (an organic additive), and<br />
toilet-paper pulp for strength (one roll of toilet paper for every 10<br />
kilograms of wet clay).<br />
<strong>Floating</strong> <strong>Clay</strong> can be thrown, but the forms I threw slumped a<br />
lot in the kiln. Perhaps decreasing the silicon carbide, or firing to<br />
a slightly cooler temperature, might have helped. Give it a try!<br />
PHOTOS: SHINJI OTANI
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