Zinc phosphide

Zinc phosphide can be prepared by the reaction of zinc with phosphorus; however, for critical applications, additional processing to remove arsenic compounds may be needed.F. Wagenknecht and R. Juza "Zinc Phosphides" in Handbook of Preparative Inorganic Chemistry, 2nd Ed. Edited by G. Brauer, Academic Press, 1963, NY. Vol. 1. p. 1080-1.

:6 Zn + P₄ → 2 Zn₃P₂

Another method of preparation include reacting tri-n-octylphosphine with dimethylzinc.{{cite journal|last1=Luber|first1=Erik J.|last2=Mobarok|first2=Md Hosnay|last3=Buriak|first3=Jillian M.|title=Solution-Processed Zinc Phosphide (α-Zn₃P₂) Colloidal Semiconducting Nanocrystals for Thin Film Photovoltaic Applications|journal=ACS Nano|volume=7|issue=9|year=2013|pages=8136–8146|issn=1936-0851|doi=10.1021/nn4034234|pmid=23952612}}

Zinc phosphide reacts with water to produce highly toxic phosphine (PH₃) and zinc hydroxide (Zn(OH)₂):

:Zn₃P₂ + 6 H₂O → 2 PH₃ + 3 Zn(OH)₂

Zn₃P₂ has a room-temperature tetragonal form that converts to a cubic form at around 845 °C.Evgeniĭ I︠U︡rʹevich Tonkov, 1992, High Pressure Phase Transformations: A Handbook, Vol 2, Gordon and Breach Science Publishers, {{ISBN|9782881247590}} In the room-temperature form there are discrete P atoms, zinc atoms are tetrahedrally coordinated and phosphorus six coordinate, with zinc atoms at 6 of the vertices of a distorted cube.Wells A.F. (1984) Structural Inorganic Chemistry 5th edition Oxford Science Publications {{ISBN|0-19-855370-6}}

The crystalline structure of zinc phosphide is very similar to that of cadmium arsenide (Cd₃As₂), zinc arsenide (Zn₃As₂) and cadmium phosphide (Cd₃P₂). These compounds of the Zn-Cd-P-As quaternary system exhibit full continuous solid-solution.{{Cite journal|title=Compounds and solid solutions of the Zn-Cd-P-As system in semiconductor electronics|journal=Inorganic Materials|last1=Trukhan|first1=V. M.|volume=50|pages=868–873|last2=Izotov|first2=A. D.|issue=9|doi=10.1134/S0020168514090143|year=2014|last3=Shoukavaya|first3=T. V.|s2cid=94409384}}

Zinc phosphide is an ideal candidate for thin film photovoltaic applications, for it has strong optical absorption and an almost ideal band gap (1.5eV). In addition to this, both zinc and phosphorus are found abundantly in the Earth's crust, meaning that material extraction cost is low compared with that of other thin film photovoltaics. Both zinc and phosphorus are also nontoxic, which is not the case for other common commercial thin film photovoltaics, like cadmium telluride.{{cite journal|doi=10.1021/nn4034234 | volume=7 | issue=9 | title=Solution-Processed Zinc Phosphide (α-Zn 3 P 2 ) Colloidal Semiconducting Nanocrystals for Thin Film Photovoltaic Applications | journal=ACS Nano | pages=8136–8146 | last1 = Luber | first1 = Erik J.| year=2013 | pmid=23952612 }}

Researchers at the University of Alberta were the first to successfully synthesize colloidal zinc phosphide. Before this, researchers were able to create efficient solar cells from bulk zinc phosphide, but their fabrication required temperatures greater than 850 °C or complicated vacuum deposition methods. By contrast, colloidal zinc phosphide nanoparticles, contained in a zinc phosphide “ink”, allows for inexpensive, easy large-scale production, by means of slot-die coating or spray coating.{{cite web |url=http://nanotechweb.org/cws/article/tech/54627 |url-status=dead |archive-url=https://web.archive.org/web/20130916163436/http://nanotechweb.org/cws/article/tech/54627 |archive-date=2013-09-16 |title=Colloidal zinc phosphide for photovoltaics - nanotechweb.org}}

The testing and development of these zinc phosphide thin films is still in its early stages, but early results have been positive. Prototype heterojunction devices fabricated from zinc phosphide nanoparticle ink exhibited a rectification ratio of 600 and photosensitivity with an on/off ratio near 100. These are both acceptable suitability benchmarks for solar cells. Development still needs to be made on optimizing the nanoparticle ink formation and device architecture before commercialization is possible, but commercial spray-on zinc phosphide solar cells may be possible within ten years.{{Cite web|url=http://www.solarnovus.com/zinc-phosphide-nonocrystals-for-spray-on-solar-thin-films_N7005.html|title = Home}}

Metal phosphides have been used as rodenticides. A mixture of food and zinc phosphide is left where the rodents can eat it. The acid in the digestive system of the rodent reacts with the phosphide to generate toxic phosphine gas. This method of vermin control has possible use in places where rodents are immune to other common poisons. Other pesticides similar to zinc phosphide are aluminium phosphide and calcium phosphide.

: Zn₃P₂ + 6H⁺ → 3Zn⁺⁺ + PH₃ ↑{{Cite web|title=Zinc Phosphide Technical Fact Sheet|url=http://npic.orst.edu/factsheets/archive/znptech.html#:~:text=Phospine%20in%20this%20fact%20sheet%20refers%20to%20the%20gaseous%20form%20of%20this%20compound%20The%20chemical%20reaction%20that%20releases%20phosphine%20is11:%20Zn3P2%20+%206H%20%E2%86%92%20PH3%20%E2%86%91%20+%203Zn++|access-date=|website=npic.orst.edu}}

Zinc phosphide is typically added to rodent baits in amount of around 0.75-2%. Such baits have a strong, pungent garlic-like odor characteristic of phosphine liberated by hydrolysis. The odor attracts rodents, but has a repulsive effect on other animals; However, birds, notably wild turkeys, are not sensitive to the smell. The baits have to contain sufficient amount of zinc phosphide in sufficiently attractive food in order to kill rodents in a single serving; a sublethal dose may cause aversion towards zinc phosphide baits encountered by surviving rodents in the future.

Rodenticide-grade zinc phosphide usually comes as a black powder containing 75% of zinc phosphide and 25% of antimony potassium tartrate, an emetic to cause vomiting if the material is accidentally ingested by humans or domestic animals. However, it is still effective against rats, mice, guinea pigs and rabbits, none of which have a vomiting reflex.{{cite web|url=http://www.ratbehavior.org/vomit.htm |title=Why rats can't vomit |publisher=Ratbehavior.org |access-date=2013-08-17}}

The New Zealand Environmental Protection Authority has approved the import and manufacture of Microencapsulated Zinc Phosphide (MZP Paste) for the ground control of possums. The application was made by Pest Tech Limited, with support from Connovation Ltd, Lincoln University and the Animal Health Board. It will be used as an additional vertebrate poison in certain situations. Unlike 1080 poison, it cannot be used for aerial application.{{cite web

| last = Environment Risk Management Authority New Zealand| title = Zinc phosphide pest poison approved with controls| access-date = 2011-08-14| url = http://www.epa.govt.nz/news/erma-media-releases/Pages/Zinc-phosphide-pest-poison-approved-with-controls-.aspx}}

Zinc phosphide is highly toxic, especially when ingested or inhaled. The reason for its toxicity is the release of phosphorus compounds, usually phosphine, when it reacts with water and acids. Phosphine is very toxic and, with trace amounts of P₂H₄, pyrophoric. Phosphine is also denser than air and may remain close to the ground without sufficient ventilation.

{{Reflist}}

• [http://extoxnet.orst.edu/pips/zincphos.htm Zinc Phosphide Pesticide Information Profile - Extension Toxicology Network]
• [http://www.epa.gov/pesticides/factsheets/chemicals/rodenticides_fs.htm EPA Proposed Risk Mitigation Decision for Nine Rodenticides]
• {{PPDB|1730}}
• [http://www.michigan.gov/dnr/0,1607,7-153-10370_12150_12220-26326--,00.html Zinc phosphide properties and use in Michigan]
• [https://web.archive.org/web/20071008081142/http://milmed.pmk.ac.th/md0173%20PESTICIDES%20IN%20THE%20MILITARY.pdf MD0173] - Pesticides in the military

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Category:Phosphides

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Category:Rodenticides

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