There is one day left to vote for the Etsy Beadweavers Team Challenge this month. The theme is "Sizzling Sunshine and "Soothing Water".

One of our team members, beadn4fun, made some treasuries of the entries. Here is a quick preview of the fabulous work our team produced. But you need to go to the team blog to vote.

Click here to vote!

Why Does Labradorite Flash?

We all have our favorite stones; mine is labradorite. Labradorite is a transluscent, gray stone. What makes it special is the flash of color - viewed at the right angle, you can see flashes of bright aqua blue, green, yellow or orange. You can see the flash in these labradorite cubes I bought a few months ago.

The flash is beautiful but why does it happen?

This is where my nerdy, engineering background is going to show through. I did some reading on mineralogy. I found out that the flash is called "Schiller effect". To understand Schiller effect, you need to be able to visualize how labradorite forms.

Labradorite is in a family of minerals called feldspars, which are classified by their chemical composition. Feldspars have a crystal lattice made up of silicon, aluminum and oxygen. In addition, depending on the type of feldspar, the crystal may contain potassium, calcium, sodium, or a mixture of calcium and sodium. Over 50% of the rock on Earth is feldspar.

The reason we aren't surrounded by gemstones is that most of these rocks cooled quickly. The molecules in the rocks are most stable chemically when they are arranged in large crystals, but the rapid cooling caused them to frozen in place before they could arrange themselves. Thus most rocks are made of a mishmash of microscopically small crystals. When feldspars cool slowly - for example the molten magma is trapped underground - there is more time for the molecules to arrange themselves into large crystals before they are locked into place.

Now here is the really interesting part: when a mixture transforms from a liquid to a solid, the result can be... complicated. The first crystals to solidify (at a higher temperature) have a different composition than the last crystals to solidify (at a lower temperature). In industry, this principal is used to separate out impurities and create very pure substances.

In any case, as feldspars cool and form crystals, the composition of the crystals being formed changes. In the real world, the temperature of the forming crystals can fluctuate up and down. This helps create layers inside the crystal with slightly different compositions.

Labradorite forms when the crystals contain a mixture of sodium and calcium. As labradorite forms into a crystal, the composition of calcium and sodium varies. The changes in composition forms layers inside the labradorite crystals. The layers inside the crystal affect light as it travels through the crystal. If you look at the layer from the right angle, you see the Schiller effect – the flash of color.

New Photos

Up to this point, I've been focused only on list new items, not revising the items I have already listed. Lately I've decided that to try re-doing some of my listings.

Here are some examples:

Stylish Stripes
Old... New...

Grapevine Necklace
Old... New...

Sweet Blossom Necklace
Old... New...

Fall Striped Bracelet
Old... New...

What do you think?

If you want to see more, you can look in my shop. I've finished the first 8 listings.