Limit Formula

Key phrases linking here: balanced chemistry, target formula, limit formulas, limit formula - Learn more

The term 'limit formula' historically has typically referred to efforts to establish absolute ranges for mixtures of oxides that melt well at an intended temperature and are not in sufficient excess to cause defects. These formulas typically show ranges for each oxide commonly used in a specific glaze type (as opposed to the concept of a limit recipe that expresses normal material amounts expected in a given type of product).

Many prefer the term "target formula". This is because the term 'limit formula' suggests that glazes outside the ranges will not work and that ones inside are somehow safe. However, this is not the case. Melting well simply carries with it a much higher likelihood that a glaze is reasonably functional and balanced (does not have excessive amounts of any individual oxide that might lead to instability or reactivity). These limits are also dependent on the amount of B₂O₃ present (if more can be tolerated, then more Al₂O₃ and SiO₂ can also be tolerated).

Specific ceramic industries have created proprietary limits for the glazes that they make (e.g. super low expansion, high abrasion resistance, resistance to bacteria growth, high elasticity, specific colors, fast fire). These limits are often closely guarded secrets and would be well outside normal the ranges shown here. A common public domain target example is crystalline glazes; they require almost no alumina, much higher than normal sodium and zinc. They also require special treatment during firing.

There is a difference between sourcing an oxide from a frit or raw material. Frits readily release their oxides to the glaze melt, giving more time for them to participate intimately in the formation of a homogeneous glaze structure (this is especially important where materials have high melting temperatures). Thus, oxides like BaO, that might potentially leach in a glaze where they are sourced from raw materials might not do so from a frit, especially when levels are relatively low.

However, we are mainly concerned with creating glazes for use on functional ware. Using the term "target formula" instead of "limit formula" suggests we are more interested in comparing a new glaze with one we already understand (have used and tested extensively). It recognizes that judging the suitability of glazes is more of a relative than absolute science. This is good.

Here is an example of a typical limit formula for cone 6 glazes.

CaO - 0-0.55
MgO - 0-0.325
KNaO - 0-0.375
ZnO - 0-0.3
BaO - 0-0.4
B₂O₃ - 0-0.35
Al₂O₃ - 0.285-0.64
SiO₂ - 2.4-4.7

These values refer to comparative numbers of molecules. They are meant to be compared with a glaze whose formula has been unified (fluxes, or melters, add up to one). At cone 6, the fluxes are CaO to BaO. They balance against the Al₂O₃ (stabilizer) and SiO₂ (glass former). The B₂O₃ is a low-temperature glass that also functions as a flux.

This suggests that CaO (usually from calcium carbonate or wollastonite) can be anywhere from zero to 0.55. But in actual practice, you will almost never see a glaze with zero CaO, there is almost always a significant amount (0.3 or more). In matte glazes, the CaO is very often higher than this limit.

-MgO (from talc and dolomite) is less common in than CaO or KNaO in glazes; it tends to matte them when the amount gets to 0.3 and higher. In fact, silky matte glazes, which are very common, will often have 0.35 or more.

-KNaO (combined total K₂O and Na₂O from feldspars and frits) is a key melter. Like CaO, almost all glazes have it. Glazes fire to a brilliant gloss when this is higher. But KNaO has high thermal expansion so the limiting factor is crazing susceptibility on your body (which will likely place it below limit expressed here).

-ZnO is an auxiliary melter; it is not common in slow-fire glazes (e.g. for pottery), especially when sourced from zinc oxide. Because other melters (especially boron) have so many less side effects (e.g. glaze defects, maleffects on color), it will almost never reach this 0.3 limit. However, in fast-fire industrial applications (1 to 2 hour firings) it can be tolerated when sourced from frits and will reach this limit.

-BaO is treated with caution because of toxicity; any glaze that has 0.4 BaO would be off-the-scale for potential to leach! That aside, the only time BaO would be at this high limit should be for special-purpose, non-functional, crystal matte or blue matte glazes. However, even though the glaze is not being used for functional ware, the potter making the ware is exposed to high levels of raw barium. For functional glazes low BaO levels can often be tolerated (e.g. 0.05-0.1) if the glaze chemistry is balanced (enough SiO₂ and Al₂O₃) and melting well (but not crystallizing). Industry often employs frits to source BaO, they are obviously much safer to use.

-SrO, although not shown, could be considered like BaO (it is not toxic and is a common auxiliary flux).

-Li₂O is also not shown. Use only a small amount (e.g. 0.05), it is a powerful flux. It also has toxicity issues.

-B₂O₃ is needed in almost all middle temperature glazes; they just will not melt enough without it. The upper limit here is conservative, but a well-melting glaze can still be achieved with levels below this (e.g. 0.2). But if you need a glaze that has a high gloss with colorant and opacifiers, or variegated reactive visual effects, then significantly more than 0.35 would likely be needed (double this amount is not unusual!). However, this limit is likely a reflection of the needs of industry; they have reason to minimize boron because of its side effects (boron blue and devitrification, micro bubbles, durability issues, difficulty with fast fire).

-Al3O₃ is needed in all glazes (except crystalline). It holds the melt from running down off vertical surfaces, stabilizing it. It also imparts hardness and durability. Generally, you want as much as possible (but if there is too much, gloss will be lost) and more than that it won't melt (it would be very unusual to see the 0.64 upper limit). Around 0.4 would be much more typical.

-SiO₂ makes up the bulk of all glazes; it is the glass former. The more the glaze will take (and still melt well), the better. All of its effects are beneficial. This upper limit is conservative; if more boron (or auxiliary fluxes like Li₂O, ZnO) are present, more SiO₂ can be tolerated.

-Colorants (e.g. oxides of Fe, Co, Mn, Cu, Cr). Be sensible. If 1% cobalt gives a bright blue, do not put in 5%. If 5% stain is enough, do not put in 10%. Iron is not dangerous. Copper can make a glaze leachable; test it. MnO makes fumes during firing. Cadmium and lead obviously require know-how to use safely.

-Titanium and Rutile: These are commonly added to variegate glazes (crystallize and produce phase changes). They are effective up to about 5%; above that, the surface will usually become rough and matte (a mesh of crystals). There are crow-bar ways to prevent this, like incorporating significant zinc or lithium. But such glazes are notoriously finicky and difficult. Beware.

Physical Limits: Is the glaze well melted? Can you scratch it with metal? Will it survive a leaching test? Is it heavily crystallized? (Do a close-up with your camera and zoom it). Is the melted glass full of air bubbles? Is it crazing? These are obvious things, but there is not much sense in fussing over chemistry if there are obvious problems like these!

Most people with lots of experience mixing and testing glazes and watching their chemistry would likely rationalize these limits in a similar way as done here. Once you have this outline fixed in mind, you will never need to look at another limit chart; it becomes second nature!

There is a link to a lengthy article on limits below.

This picture has its own page with more detail, click here to see it.

Ceramic material powders can be crystalline or amorphous (or a combination), and they can be natural or man-made, and they can have very different particle physics. Ceramic materials are classic case studies of the sciences of solid state physics and solid state chemistry. Mineral sources of oxides impose their own melting patterns in glazes. When oxides are then supplied by a different material, a new "system" is entered. An extreme example of this is sourcing Al₂O₃ to a glaze using calcined alumina instead of kaolin. Although the chemical formula of the glaze, as a whole, may remain unchanged, the fired result would be completely different. This is because very little of the alumina would dissolve into the glaze melt. At the opposite extreme, a different frit could be used to supply a set of oxides (while maintaining the overall chemistry of the glaze), and the fired result would be much more chemically predictable. Why? Because they readily release their oxides to the melt.

Does adding boron alone always increase glaze melt?

This picture has its own page with more detail, click here to see it.

Boron (B₂O₃) is like silica, but it is also a flux. Frits and Gerstley Borate supply it to glazes. In this test, I increased the amount of boron from 0.33 to 0.40 (using the chemistry tools in my insight-live.com account). I was sure that this would make the glaze melt more and have less of a tendency to craze. But as these GBMF tests for melt flow (10 gram GBMF test balls melted on porcelain tiles) show, that did not happen. Why? I am guessing that to get the effect B₂O₃ has to be substituted, molecule for molecule for SiO₂ (not just added to the glaze).

A limit or target glaze formula. What does this mean?

This picture has its own page with more detail, click here to see it.

Recipes show us the materials in a the glaze powder (or slurry). Formulas enumerate the oxide molecules and their comparative quantities in the fired glass. Oxides construct the fired glass. The kiln de-constructs ceramic materials to get their oxides, discards the carbon, sulfur, etc. and builds the glass from the rest. There is a direct relationship between fired glaze properties (e.g. melting range, gloss, thermal expansion, hardness, durability, color response, etc) and its oxide formula. There are 8-10 oxides to know about (vs. hundreds of materials). From the formula-viewpoint materials are thus "sources-of-oxides". While there are other factors besides pure chemistry that determine how a glaze fires, none is as important. Insight-live can calculate and show the formula of a recipe, this enables comparing it side-by-side and with a target formula (or another recipe known to work as needed). Target formulas are opened using the advanced recipe search, choosing the limits batch and clicking/tapping the search button (search 'target recipe' in Insight-live help for more info).