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Instructions
Chrome oxide is a very powerful colorant that can at times be fickle. It mostly gives a wonderful range of strong greens, but it can also produce blues, browns, and even reds.
Defining the Terms
Chrome Oxide (Cr203): An amphoteric/ refractory that melts at 4109°F, and volatilizes at 2192°F. It is a green powder used by potters that doesn’t dissolve well in a glaze melt, resulting in opaque, mainly green colors. Red, pink, gray, brown, and orange colors are also possible.
Iron Chromate (Fe203 Cr203 or FeCr03 ): An iron–chromium ore commonly used to produce grays. It gives opacity and can be used with cobalt, iron, and manganese oxides to produce blacks. With tin in oxidation, it can develop a pinkish gray.
Potassium Dichromate (K2Cr207 ): A bright orange crystalline material that is generally used at low-temperatures to create bright reds with lead frits in oxidation. It is toxic and soluble.
Amphoteric: A material capable of acting as an acid (glass-former) or a base (alkaline flux) in a glaze. Acts as a bridge between the two depending on the situation.
Toxicity: While there is no legal limit set for safe leaching of chrome in glazes, potters should be aware that the legal level of allowable chrome oxide deemed safe for drinking water is 0.1 mg/L (ppm). Because chromium can have different valences, its toxicity and carcinogenic effects vary greatly. It is volatile at higher temperatures and is a toxic fume (fugitive chrome). Care should be taken when handling and firing chrome compounds.
Properties and Characteristic
Chrome produces a wide range of greens, from a transparent glossy lime green to the more iconic, opaque, satin kelly green. The strong green color can often be modified by very small amounts of other oxides, like cobalt oxide, copper oxide, iron oxide, manganese dioxide, rutile, tin oxide, etc. In addition to green, chrome oxide also produces gray, brown, red, pink, and orange colors. It is also used in black glazes and stains to give a strong, true black color. Chrome oxide comes to potters as a bright green powder derived from iron chromate. It is a very powerful colorant—even 0.1% can give a green color.
Chrome is unaffected by oxidation and reduction but sometimes glazes that use chrome oxide appear to be affected by reduction because they also contain other oxides to influence their color and those are affected by reduction (like tin oxide, copper oxide, etc.).
Chrome oxide is an amphoteric oxide, which means it plays an intermediate role between fluxes and silica. It is generally very refractory and not very soluble in a glaze melt but sometimes it acts as a flux, e.g. as with the acidic tin oxide. The exact color it produces depends on the role chrome is fulfilling in the glaze. For example, in high alkaline or high boron glaze bases, when less than 1% chrome is added, it can dissolve well and give bright glossy transparent greens, (see Odyssey series 0.15/0.5%). In a zinc (zinc chromate) base it produces browns (see Chun glazes). In a high calcium or high strontium base without zinc, it can produce pinks, or crimson to burgundy colors (see Raspberry and Cranberry glaze). In a glaze that contains tin oxide, adding chrome pushes it toward shades of pink. The colors of chrome-tin pinks can be quite variable but consistent chrome-tin colors can be achieved by using commercial stains where the chrome and tin combination have been pre-melted together.
Less than 1% chrome oxide usually disperses in a glaze melt but occasionally it may cause speckling. To disperse the color evenly, depending on the stiffness of the base, it may require ball milling.
Because chrome produces such strong opaque greens, it is often used as a decorator color rather than a single glaze for the piece (see Temmoku Gold and Odyssey green glaze). Other techniques may include using a dark clay body, glazing with a chrome green, and after firing, sandblasting the piece to give it visual interest.
Because chrome oxide is volatile, placing a chrome green glaze next to a tin white glaze will often produce pink flashes on the tin white glaze. A good kiln vent can help to pull out the chrome fumes before they have time to latch onto the tin whites. But chrome flashing is best avoided by not mixing the two glazes in the same firing. Alternatively, if you like the pink flashing, this can be encouraged by mixing chrome greens and tin whites in a firing or even firing pieces in a partially closed saggar with a chrome green glaze painted on the inside wall of the saggar.
Chrome oxide gives a burgundy/red when combined with tin oxide at cone 6 in oxidation (see Raspberry, Cranberry or Chrome Red glazes). This iconic cone 6 glaze needs a specific formulation to be successful. First, there needs to be a specific ratio of tin oxide to chrome oxide. Start with 0.1–0.5% chrome oxide and 7.5–9.0% tin oxide. Remember that these are targets that should help you, but you can get red colors to develop with less amounts of tin oxide (see Cranberry glaze with 3.5% tin oxide). Varying the amounts will give a variety of pinks to deep burgundy colors. The calcium content of the glaze should be high (10–15% or 0.7–0.9 moles). It is also important to have no zinc in the recipe or the glaze will turn brown. Alumina is also best if kept low. Some recommend no magnesium oxide (talc, dolomite, or magnesium carbonate) in the base recipe while others use small amount of MgO to achieve interesting red/burgundy colors (see Burgundy/Red glaze). A thin application is best as a thicker coating may produce a gray glaze.
You can also get chrome/tin reds at low-fire temperatures but they don’t work well above cone 8. If you don’t want to mess with the ratio of tin to chrome, an easy way to get cone 6 burgundy reds is to simply add 5–8% stain, such as Mason Deep Crimson 6006, (which contains calcium, chrome, tin, and silica), to a high-calcium base glaze (see Cranberry glaze).
Adding cobalt carbonate to a chrome/tin or burgundy/red can push the glaze toward purple but adding too much will overpower the red (see Raspberry and Chrome Red glaze tiles with added cobalt carbonate). You can also alter the tone of the burgundy/red glaze with small additions of iron oxide, rutile, or manganese dioxide.
Note: All glazes shown here were fired on porcelain and in an electric kiln except where noted otherwise.
This article was written by John Britt and excerpted from the November 2012 issue of Ceramics Monthly.
Recipe Topics
Clay Bodies and Casting Slips
Low Fire (Cone 022 – 01)
Mid Range (Cone 1 – 7)
High Fire (Cone 8 – 14)
Raku
Salt, Soda, and Wood
Slip, Engobe, and Terra Sigillata
Reference
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