Cadmium telluride explained

Cadmium telluride (CdTe) is a stable crystalline compound formed from cadmium and tellurium. It is mainly used as the semiconducting material in cadmium telluride photovoltaics and an infrared optical window. It is usually sandwiched with cadmium sulfide to form a p–n junction solar PV cell.

Applications

See also: Cadmium telluride photovoltaics.

CdTe is used to make thin film solar cells, accounting for about 8% of all solar cells installed in 2011.[1] They are among the lowest-cost types of solar cell,[2] although a comparison of total installed cost depends on installation size and many other factors, and has changed rapidly from year to year. The CdTe solar cell market is dominated by First Solar. In 2011, around 2 GWp of CdTe solar cells were produced;[3] For more details and discussion see cadmium telluride photovoltaics.

CdTe can be alloyed with mercury to make a versatile infrared detector material (HgCdTe). CdTe alloyed with a small amount of zinc makes an excellent solid-state X-ray and gamma ray detector (CdZnTe).

CdTe is used as an infrared optical material for optical windows and lenses and is proven to provide a good performance across a wide range of temperatures.[4] An early form of CdTe for IR use was marketed under the trademarked name of Irtran-6, but this is obsolete.

CdTe is also applied for electro-optic modulators. It has the greatest electro-optic coefficient of the linear electro-optic effect among II-VI compound crystals (r41=r52=r63=6.8×10−12 m/V).

CdTe doped with chlorine is used as a radiation detector for x-rays, gamma rays, beta particles and alpha particles. CdTe can operate at room temperature allowing the construction of compact detectors for a wide variety of applications in nuclear spectroscopy.[5] The properties that make CdTe superior for the realization of high performance gamma- and x-ray detectors are high atomic number, large bandgap and high electron mobility ~1100 cm2/V·s, which result in high intrinsic μτ (mobility-lifetime) product and therefore high degree of charge collection and excellent spectral resolution.[6] Due to the poor charge transport properties of holes, ~100 cm2/V·s, single-carrier-sensing detector geometries are used to produce high resolution spectroscopy; these include coplanar grids, Frisch-collar detectors and small pixel detectors.

Physical properties

5.9×10−6/K at 293 K[7]

52 GPa

0.41

Optical and electronic properties

Bulk CdTe is transparent in the infrared, from close to its band gap energy (1.5 eV at 300 K,[8] which corresponds to infrared wavelength of about 830 nm) out to wavelengths greater than 20 μm; correspondingly, CdTe is fluorescent at 790 nm. As the size of CdTe crystals are reduced to a few nanometers or less, thus making them CdTe quantum dots, the fluorescence peak shifts through the visible range into the ultraviolet.

Chemical properties

CdTe is insoluble in water.[9] CdTe has a high melting point of with evaporation starting at .[10] CdTe has a vapor pressure of zero at ambient temperatures. CdTe is more stable than its parent compounds cadmium and tellurium and most other Cd compounds, due to its high melting point and insolubility.[11]

Cadmium telluride is commercially available as a powder, or as crystals. It can be made into nanocrystals.

Toxicology assessment

The compound CdTe has different qualities than the two elements, cadmium and tellurium, taken separately. CdTe has low acute inhalation, oral, and aquatic toxicity, and is negative in the Ames mutagenicity test. Based on notification of these results to the European Chemicals Agency (ECHA), CdTe is no longer classified as harmful if ingested nor harmful in contact with skin, and the toxicity classification to aquatic life has been reduced.[12] Once properly and securely captured and encapsulated, CdTe used in manufacturing processes may be rendered harmless. Current CdTe modules pass the U.S. EPA's Toxicity Characteristic Leaching Procedure (TCLP) test, designed to assess the potential for long-term leaching of products disposed in landfills.[13]

A document hosted by the U.S. National Institutes of Health[14] dated 2003 discloses that:

According to the classification provided by companies to the European Chemicals Agency (ECHA) in REACH registrations, it is still harmful to aquatic life with long lasting effects.

Additionally, the classification provided by companies to ECHA notifications classifies it as very toxic to aquatic life with long lasting effects, very toxic to aquatic life, harmful if inhaled or swallowed and is harmful in contact with skin.[15]

Availability

At the present time, the prices of the raw materials cadmium and tellurium are a negligible proportion of the cost of CdTe solar cells and other CdTe devices. However, tellurium is a relatively rare element (1–5 parts per billion in the Earth's crust; see Abundances of the elements (data page)). Through improved material efficiency and increased PV recycling systems, the CdTe PV industry has the potential to fully rely on tellurium from recycled end-of-life modules by 2038.[16] See Cadmium telluride photovoltaics for more information. Another study shows that CdTe PV recycling will add a significant secondary resource of Te which, in conjunction with improved material utilization, will enable a cumulative capacity of about 2 TW by 2050 and 10 TW by the end of the century.[17]

See also

External links

Notes and References

  1. Web site: Photovoltaics report. dead. https://web.archive.org/web/20121105154721/http://www.ise.fraunhofer.de/de/downloads/pdf-files/aktuelles/photovoltaics-report.pdf. 2012-11-05.
  2. Book: 10.1002/9783527633708.ch1. Introduction. Chalcogenide Photovoltaics. 1–8. 2011. 9783527633708.
  3. Web site: Photovoltaics report. dead. https://web.archive.org/web/20121105154721/http://www.ise.fraunhofer.de/de/downloads/pdf-files/aktuelles/photovoltaics-report.pdf. 2012-11-05.
  4. Web site: Cadmium Telluride.
  5. Book: Properties of Narrow-Gap Cadmium-Based Compounds. P. Capper . INSPEC, IEE. London, UK. 1994. 978-0-85296-880-2.
  6. Characterization of M-π-n CdTe pixel detectors coupled to HEXITEC readout chip. Journal of Instrumentation . 7 . 1 . C01035 . 10.1088/1748-0221/7/01/C01035. 2012 . Veale . M. C. . Kalliopuska . J. . Pohjonen . H. . Andersson . H. . Nenonen . S. . Seller . P. . Wilson . M. D. . 2012JInst...7C1035V . free .
  7. Web site: Properties of II-VI Compound Semiconductors . D W . Palmer . Semiconductors-Information . March 2008.
  8. J. Phys. Chem. Solids . G. . Fonthal . Temperature dependence of the band gap energy of crystalline CdTe. 10.1016/s0022-3697(99)00254-1. 61 . 4 . 579–583 . 2000. etal. 2000JPCS...61..579F .
  9. Solubility is below 0.1mg/L which equals a classification as insoluble- reference, "ECHA Substance Registration"http://apps.echa.europa.eu/registered/data/dossiers/DISS-dffb4072-e283-47ae-e044-00144f67d031/DISS-dffb4072-e283-47ae-e044-00144f67d031_DISS-dffb4072-e283-47ae-e044-00144f67d031.html
  10. Web site: Cadmium Telluride. 2013-12-13. https://archive.today/20131213155005/http://apps.echa.europa.eu/registered/data/dossiers/DISS-dffb4072-e283-47ae-e044-00144f67d031/DISS-dffb4072-e283-47ae-e044-00144f67d031_DISS-dffb4072-e283-47ae-e044-00144f67d031.html. 2013-12-13. dead.
  11. Web site: [ftp://ftp.co.imperial.ca.us/icpds/eir/campo-verde-solar/final/evaluating-toxicity.pdf Evaluating the read-across approach on CdTe toxicity for CdTe photovoltaics ]. S. Kaczmar . 2011 .
  12. Web site: Scientific Comment of Fraunhofer to Life Cycle Assessement of CdTe Photovoltaics . Fraunhofer Center for Silicon Photovoltaics CSP . dead . https://web.archive.org/web/20131213174834/http://www.csp.fraunhofer.de/presse-und-veranstaltungen/details/id/47/ . 2013-12-13 .
  13. Web site: CdTe PV: Real and Perceived EHS Risks . V. Fthenakis . K. Zweibel . National Renewable Energy Laboratory . 2003.
  14. Nomination of Cadmium Telluride to the National Toxicology Program . United States Department of Health and Human Services . 2003-04-11.
  15. Web site: Cadmium telluride - Brief Profile - ECHA. European Chemicals Agency. 2020.
  16. M. Marwede . A. Reller . 2012 . Future recycling flows of tellurium from cadmium telluride photovoltaic waste. 69 . 35–49. Resources, Conservation and Recycling. 10.1016/j.resconrec.2012.09.003.
  17. Fthenakis . V.M. . 2012 . Sustainability metrics for extending thin-film photovoltaics to terawatt levels . MRS Bulletin . 37 . 4. 425–430 . 10.1557/mrs.2012.50 . free .