Birefringent optical crystals


	*Birefringent Optical Crystals*

The division of light into two components (an "ordinary" and an "extraordinary ray") found in materials have two different indices of refraction in different directions (i.e. when light entering certain transparent materials, such as calcite, splits into two beams which travel at different speeds). Birefringence is also known as double refraction. Crystals possessing and exhibiting birefringence include hexagonal (such as calcite), tetragonal, and trigonal crystal classes, and are known as uniaxial. Orthorhombic, monoclinic, triclinic exhibit three indices of refraction. They are therefore trirefringent and are known as biaxial. Birefringent prisms include the Nicol prism, Glan-Foucault prism, Glan-Thompson prism, and Wollaston prism.
Another material, an excellent birefringence optical crystal undoped YVO4 is newly developed. It has very good transmission in a wide wavelength range from visible to infrared, large index of refractivity and birefringence difference. Compared to other important birefringence crystals, YVO4 has higher hardness, better fabrication property, water insoluble and man-made than calcite (CaCO3 single crystal); easier to get large, high quality crystal and lower cost than rutile (TiO2 single crystal). Those outstanding properties make YVO4 very important birefringence optical material and widely used in opto-electronic research, development and industry. For example, the optical communication system needs a huge quantity devices of undoped YVO4, such as fiber optical isolators, circulators, beam displacers, Glan polarizers and other polarizing devices.

We deliver all kinds of birefringent crystals, especially the YVO4 and TiO2 crystals and parts made from them for passive optical and polarization components. If you have any need for birefringent crystals, please feel free to contact us. Our engineers will help you choose the most suitable crystal for your application. The highest quality and lowest prices are our commitments.

Crystal	Birefringence D=he-ho	Refractive index h at l= 0.63 µm	Thermal optical Coef. dh/dT 10^-6/°K	Structure and lattice constant, Å	Melting point ^°C	Density g/ cm³	Hardness (Mohs)	Thermal Coef. 10^-6/K
TiO₂ (rutile)	+ 0.282	ho=2.583 he=2.865	a: -0.72 c: -0.42	Tetragonal a=4.593 c=2.958	1840	4.26	7	a: 7.14 c: 9.19
YVO₄	+ 0.222	ho=1.9929 he=2.2154	a: -8.5 c: -3.0	Tetragonal a=7.12, c= 6.29	1825	4.22	5	a: 4.46 c: 11.37
CaCO₃ (calcite)	- 0.1705	ho=1.6557 he=1.4852	-	Rhomb. a= 4.989 c= 17.062	1339	2.715	3	a:24.39 c: 5.68
PbMoO₄	- 0.124	ho=2.386 he=2.262	a: 0.41 c: 0.72	Tetragonal a=5.435 c=12.11	1065	6.9	3	-
TeO₂ (paratellurite)	- 0.118	ho=2.260 he=2.142	-	Tetragonal a=4.81 c=7.613	730	5.99	4.5	-
LiNbO₃	- 0.086	ho=2.286 he=2.203	a: 0.53 c: 5.60	Hexagonal a=5.15 c= 13.86	1255	4.64	5	a: 16.7 c: 2.0
MgF₂	+ 0.012	ho=1.3836 he=1.3957	-	Tetragonal a=4.64 c=3.06	1312	3.18	3	a: 13.7 c:8.48
SiO₂ (quartz)	+ 0.009	ho=1.5427 he=1.5518	-	Hexagonal a=5.15 c= 13.86	1610	2.66	5	7.07

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