I lifted this diagram from some astronomy lecture notes, of all places; if this is infringement let me know, and I will politely remove them. What this diagram tells you, basically, is that feldspars form with two broad swaths of composition: sodium-potassium rich (alkali feldspars), and sodium-calcium rich (plagioclase feldspars). Na and K trade off because they have similar charges. Na and Ca trade off because they have similar ionic radii. They do not have the same charge, and this is compensated by Na taking one more Si (+4) and one less Al (+3), while calcium does the reverse. Remember, labradorite would occupy a fifth of the bottom swath, from the middle, near the "o" in "Plagioclase" to the right, to maybe the divide between the "s" and the "e."
The above is schematic, but basically approximates what a minerologist would call the "hot" feldspar curve. I have modified it with blatant disregard for hard data below, but the general principles, I think, are accurate. If the feldspar cools slowly (note we are dealing with a fairly large crystal here; this sample cooled very slowly underground), some of the mid-range compositions are not stable; an initially crystallizing feldspar at the composition of the "o" will "exsolve." Some regions will become Na-enriched, and other regions Ca enriched. So instead of a single continuous composition of "o," it ends up with alternating regions of composition "Pl" and regions of composition "se." And if those regions are in a size range approximating the wavelength of visible light, there are some amazing optical effects...
Note that this is not the intrinsic color of the mineral; it's an effect of scattering and interference from zones of slightly different compositions. It's like the "rainbow" effect of an oil slick on water. In the latter case, the layer of oil is thin enough to produce the same optical interference and resultant colors: the oil isn't actually "rainbow-colored." You can only see these colors at particular angles to the crystal lattice, which is why I had to catch this flare at an odd angle, and so much is out of focus. But it really is quite beautiful. This stone is often used in sculptures, and as facade and decorative stone in buildings- I've noticed it's used quite often for jewlery stores.
I should also make it clear that this effect is quite different from the brillant colors that sunstones can take on. In the case of Oregon's sunstones, the colors apparently arise from microscopic inclusions of metallic copper, but that may not hold true for all sunstones. The sunstones are phenocrysts in volcanic rock; they have initially formed pretty slowly, but their final cooling was quite rapid by geologic standards. They would not have undergone the gradual cooling necessary to get the alternating lamellae of varying compsitions.
One of my favorite minerals!
ReplyDeleteSuch a pretty stone.
ReplyDeleteReBecca- I am loving that little dino-biker!
ReplyDeleteDean- it's actually astonishingly common and abundant here in OR- it makes up a large proportion (50-70%, in my experience)of basalt- that ubiquitous, black ugly volcanic rock that our state is basically made of. However, as I tried to emphasize, the conditions and history needed to get this optical effect don't occur all that frequently. Still, it's used quite often for upscale buildings. Next time you're walking around downtown Portland on a sunny day, pay attention to buildings that are clad in dark gray to black stone, and watch for the little flickers of color... good chance it's this stuff.
The dino biker is near a bike shop on Main Street In Grand Junction :)
ReplyDeleteand it makes for a helluva kitchen counter top.
ReplyDelete