Manganese electrolysis During the
electrowinning of manganese, the addition of
selenium dioxide decreases the power necessary to operate the
electrolysis cells. China is the largest consumer of selenium dioxide for this purpose. For every tonne of manganese, an average 2 kg selenium oxide is used.
Glass production The largest commercial use of selenium, accounting for about 50% of consumption, is for the production of glass. Selenium compounds confer a red color to glass. This color cancels out the green or yellow tints that arise from iron impurities typical for most glass. For this purpose, various selenite and selenate salts are added. For other applications, a red color may be desired, produced by mixtures of CdSe and CdS.
Alloys Selenium is used with
bismuth in
brasses to replace more toxic
lead. The regulation of lead in drinking water applications such as in the US with the
Safe Drinking Water Act of 1974, made a reduction of lead in brass necessary. The new brass is marketed under the name EnviroBrass. Like lead and sulfur, selenium improves the machinability of steel at concentrations around 0.15%. Selenium produces the same machinability improvement in copper alloys.
Lithium–selenium batteries The lithium–selenium (Li–Se) battery was considered for energy storage in the family of lithium batteries in the 2010s.
Solar cells Selenium was used as the photoabsorbing layer in the first solid-state solar cell, which was demonstrated by the English physicist
William Grylls Adams and his student Richard Evans Day in 1876. Only a few years later,
Charles Fritts fabricated the first thin-film solar cell, also using selenium as the photoabsorber. However, with the emergence of silicon solar cells in the 1950s, research on selenium thin-film solar cells declined. As a result, the record efficiency of 5.0% demonstrated by Tokio Nakada and Akio Kunioka in 1985 remained unchanged for more than 30 years. In 2017, researchers from
IBM achieved a new record efficiency of 6.5% by redesigning the device structure. Following this achievement, selenium has gained renewed interest as a wide bandgap photoabsorber with the potential of being integrated in
tandem with lower bandgap photoabsorbers. In 2024, the first selenium-based tandem solar cell was demonstrated, showcasing a selenium top cell monolithically integrated with a silicon bottom cell. However, a significant deficit in the
open-circuit voltage is currently the main limiting factor to further improve the efficiency, necessitating defect-engineering strategies for selenium thin-films to enhance the
carrier lifetime. Recent theoretical studies using first-principles defect calculations have shown that selenium exhibits intrinsic point defect tolerance, suggesting that interfaces and extended defects are the primary factors limiting device performance. As of now, the only defect-engineering strategy that has been investigated for selenium thin-film solar cells involves
crystallizing selenium using a laser.
Photoconductors Amorphous selenium (α-Se) thin films have found application as photoconductors in
flat-panel X-ray detectors. These detectors use amorphous selenium to capture and convert incident X-ray photons directly into electric charge. Selenium has been chosen for this application among other semiconductors owing to a combination of its favorable technological and physical properties: • Amorphous selenium has a low melting point, high vapor pressure, and uniform structure. These three properties allow quick and easy deposition of large-area uniform films with a thickness up to 1 mm at a rate of 1–5 μm/min. Their uniformity and lack of grain boundaries, which are intrinsic to polycrystalline materials, improve the X-ray image quality. Meanwhile the large area is essential for scanning the human body or luggage items. • Selenium is less toxic than many compound semiconductors that contain arsenic or heavy metals such as mercury or lead. • The mobility in applied electric field is sufficiently high both for electrons and holes, so that in a typical 0.2 mm thick device, c. 98% of electrons and holes produced by X-rays are collected at the electrodes without being trapped by various defects. Consequently, device sensitivity is high, and its behavior is easy to describe by simple transport equations.
Rectifiers Selenium rectifiers were first used in 1933. They have mostly been replaced by silicon-based devices. One notable exception is in power DC
surge protection, where the superior energy capabilities of selenium suppressors make them more desirable than
metal-oxide varistors.
Other uses The demand for selenium by the electronics industry is declining.
photocells,
light meters and
solar cells. Its use as a photoconductor in plain-paper copiers once was a leading application, but in the 1980s, the photoconductor application declined (although it was still a large end-use) as more and more copiers switched to organic photoconductors.
Zinc selenide was the first material for blue
LEDs, but
gallium nitride dominates that market.
Cadmium selenide can be used to make
quantum dots. Sheets of amorphous selenium convert
X-ray images to patterns of charge in
xeroradiography and in solid-state, flat-panel X-ray cameras. 75Se is used as a gamma source in industrial radiography. Selenium catalyzes some chemical reactions, but it is not widely used because of issues with toxicity. In
X-ray crystallography, incorporation of one or more selenium atoms in place of sulfur helps with multiple-wavelength anomalous dispersion and
single wavelength anomalous dispersion phasing. Selenium is used in the
toning of photographic prints, and it is sold as a toner by numerous photographic manufacturers. Selenium intensifies and extends the tonal range of black-and-white photographic images and improves the permanence of prints. Small amounts of organoselenium compounds have been used to modify the catalysts used for the
vulcanization for the production of rubber. brands. ==Pollution==