This Specimen has been sold.
3.3" Flashy Polished Labradorite Heart - Brilliant Blue!
This is a flashy, iridescent, piece of Labradorite polished into a beautiful heart. The brilliant blue/green/gold colors have a lot of play in the light, giving the piece an entirely different personality when viewed in different angles and lighting.
This particular specimen as an extremely brilliant blue color.
This particular specimen as an extremely brilliant blue color.
About Labradorite
Labradorite is a feldspar mineral most often found in mafic igneous rocks. Some specimens of labradorite exhibit what is called a "Schiller effect"; a strong play of iridescent blue, green, red, orange, and yellow colors. Labradorite is so well known for these spectacular displays of color that the phenomenon is also known as labradorescence. Specimens with high quality labradorescence are often polished and used as gemstones.
The labradorescence is not caused by the colors breflecting on the surface of the specimen. Instead, light enters the stone, hits a twinning crystal lattice surface within the stone, and reflects from that. The color seen is the color of light reflected from that twinning surface. Different twinning surfaces within the stone reflect different colors of light. Light reflecting from different twinning surfaces in various parts of the stone can give the stone a multi-colored appearance.
Labradorite is named after Labrador, Canada, where it was first found. Today, the most prolific deposits for most commercially available labradorite occur in Madagascar and Russia.
Labradorite is a feldspar mineral most often found in mafic igneous rocks. Some specimens of labradorite exhibit what is called a "Schiller effect"; a strong play of iridescent blue, green, red, orange, and yellow colors. Labradorite is so well known for these spectacular displays of color that the phenomenon is also known as labradorescence. Specimens with high quality labradorescence are often polished and used as gemstones.
The labradorescence is not caused by the colors breflecting on the surface of the specimen. Instead, light enters the stone, hits a twinning crystal lattice surface within the stone, and reflects from that. The color seen is the color of light reflected from that twinning surface. Different twinning surfaces within the stone reflect different colors of light. Light reflecting from different twinning surfaces in various parts of the stone can give the stone a multi-colored appearance.
Labradorite is named after Labrador, Canada, where it was first found. Today, the most prolific deposits for most commercially available labradorite occur in Madagascar and Russia.