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Zinc Telluride Single Crystal

(ZnTe)

 

Zinc Telluride is the chemical compound with the formula ZnTe. This solid is an intrinsic semiconductor material with band gap of 2.23–2.25 eV. It is usually a P-type semiconductor. Its crystal structure is cubic, like that for sphalerite and diamond. It has the appearance of grey or brownish-red powder, or ruby-red crystals when refined by sublimation.

 

Crystal properties:

Crystal growth method:                Seeded Vapor-Phase Free Growth Technology

Crystal growth orientation:           (100) (110) (111) +/- 0.5°

Crystal structure:                            cubic, a = 6.1034Å

Growth direction:                            <111>

Specific resistivity:                          < 1 X 106 Ohm cm

Hall mobility:                                   130 (h) cm2 / V / sec.

EPD:                                                  < 5 X 105 / cm2

Twin:                                                 Twin free

 

Applications:
Zinc telluride has a lattice constant is 0.61034 nm, allowing it to be grown with or on Aluminium Antimonide, Gallium Antimonide, Indium Arsenide, and Lead Selenide. Zinc telluride can be also prepared as hexagonal crystals (wurzite structure). Irradiated by a strong optical beam burns in presence of oxygen. 

Optoelectronics:
Zinc telluride is important for development of various semiconductor devices, including blue LEDs, laser diodes, solar cells, and components of microwave generators.
It can be used for solar cells as a background layer and the p-type semiconductor in PIN structure (e.g. using cadmium telluride – p-type or i-type semiconductor, and cadmium sulfide – n-type semiconductor).
Zinc Telluride together with Lithium Niobate is often used for generation of pulsed terahertz radiation in time-domain terahertz spectroscopy and terahertz imaging. When a crystal of such material is subjected to a high-intensity light pulse of sub-picosecond duration, it emits a pulse of terahertz frequency through a nonlinear optical process called optical rectification. Conversely, subjecting a zinc telluride crystal to terahertz radiation causes it to show optical birefringence and change the polarization of a transmitting light, making it an electro-optic detector. 

Electro-optics:
Zinc Telluride can be easily doped, and for this reason it is one of the more common semiconducting materials used in optoelectronics.
Vanadium-doped zinc telluride, "ZnTe:V", is a non-linear optical photorefractive material of possible use in the protection of sensors at visible wavelengths. ZnTe:V optical limiters are light and compact, without complicated optics of conventional limiters. ZnTe:V can block a high-intensity jamming beam from a laser dazzler, while still passing the lower-intensity image of the observed scene. It can also be used in holographic interferometry, in reconfigurable optical interconnections, and in laser optical phase conjugation devices. It offers superior photorefractive performance at wavelengths between 600–1300 nm, in comparison with other III-V and II-VI compound semiconductors. By adding manganese as an additional dopant (ZnTe:V:Mn), its photorefractive yield can be significantly increased.

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