Silicon oxynitride

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| ImageFile = Sinoite.png

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| OtherNames = Silicon nitride oxide, dinitride disilicon oxide

|Section1={{Chembox Identifiers

| index1_label = Si₂N₂O

| CASNo1 = 12033-76-0

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| EC_number1 = 234-793-1

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|Section2={{Chembox Properties

| O=1 | Si=2 | N=2

| Appearance = Colorless crystals

| Density = 2.81 g·cm⁻³

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|Section3={{Chembox Structure

| CrystalStruct = Orthorhombic{{cite journal|title=Solid Solubility of Aluminum in O'-SiAlON|journal=J. Am. Ceram. Soc.|author= Ohashi, Masayoshi|year=1993|volume=76|pages=2112–2114|doi=10.1111/j.1151-2916.1993.tb08343.x|issue=8|display-authors=etal}}

| SpaceGroup = Cmc2₁ No 36, Pearson symbol oS20

| LattConst_a = 0.48553 nm, b = 0.52194 nm, c = 0.52194 nm, Z = 4

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Silicon oxynitride is a ceramic material with the chemical formula SiO_xN_y. While in amorphous forms its composition can continuously vary between SiO₂ (silica) and Si₃N₄ (silicon nitride), the only known intermediate crystalline phase is Si₂N₂O.{{cite journal|vauthors=Hillert M, Jonsson S, Sundman B |journal= Z. Metallkd |year=1992|volume= 83|pages= 648–654|title=Thermodynamic Calculation of the Si-N-O System}} It is found in nature as the rare mineral sinoite in some meteorites and can be synthesized in the laboratory.{{cite journal|doi=10.1126/science.165.3900.1363|title=Silicon Oxynitride Stability|year=1969|last1=Ryall|first1=W. R.|last2=Muan|first2=A.|journal=Science|volume=165|issue=3900|pages=1363–4|pmid=17817887 |bibcode=1969Sci...165.1363R|s2cid=22339579}}

Properties

File:Sinoite.png

The crystalline structure of silicon oxynitride is built by SiN₃O tetrahedra connected through oxygen atoms along the c axis and through nitrogen atoms perpendicular to it. The strong covalent bonding of this structure results in high flexural strength and resistance to heating and oxidation up to temperatures of about 1600 °C.

Synthesis

Polycrystalline silicon oxynitride ceramics are primarily produced by nitridation of a mixture of Si and silicon dioxide at a temperature above melting point of silicon (1414 °C), in the range 1420–1500 °C:

:3 Si + SiO₂ + 2 N₂ → 2 Si₂N₂O

Silicon oxynitride materials with various stoichiometries may also arise as the products of pyrolysis of preceramic polymers, namely polysilanes and polyethoxysilsesquiazane. SiON materials thus obtained are referred to as polymer derived ceramics or PDCs. By using preceramic polymers, dense or porous Si oxynitride ceramics in complex forms can be obtained using shaping techniques more typically applied for polymers.[https://www.mdpi.com/1996-1944/10/12/1391/pdf SiON PDCs]

Applications

Thin films of silicon oxynitride can be grown on silicon using a variety of plasma deposition techniques and used in microelectronics as a dielectric layer alternative to silicon dioxide and silicon nitride with the advantages of low leakage currents and high thermal stability. These films have an amorphous structure and therefore their chemical composition can widely deviate from Si₂N₂O. By changing the nitrogen/oxygen ratio in these films, their refractive index can be continuously tuned between the value of ~1.45 for silicon dioxide and ~2.0 for silicon nitride. This property is useful for gradient-index optics components such as graded-index fibers.

Silicon oxynitrides can be doped with metal atoms. The most common example is sialon, a family of quaternary SiAlON compound. Quaternary silicon oxynitrides containing a lanthanide element, such as La, Eu or/and Ce are used as phosphors.{{cite journal|doi=10.1016/j.stam.2007.08.005|format=free download|title=Silicon-based oxynitride and nitride phosphors for white LEDs—A review|year=2007|last1=Xie|first1=Rong-Jun|last2=Hirosaki|first2=Naoto|journal=Science and Technology of Advanced Materials|volume=8|issue=7–8|pages=588|doi-access=free|bibcode=2007STAdM...8..588X}}

References

{{reflist|refs=

{{cite book|author=Ralf Riedel|title=Ceramics science and technology: Structures|url=https://books.google.com/books?id=I-WFvgkBiEMC&pg=PA97|access-date=8 October 2011|date=18 April 2008|publisher=Wiley-VCH|isbn=978-3-527-31155-2|pages=97–}}

{{cite book|author1=Albert R. Landgrebe|author2=Electrochemical Society. Dielectric Science and Technology Division|author3=Electrochemical Society. High Temperature Materials Division|title=Silicon nitride and silicon dioxide thin insulating films: proceedings of the sixth international symposium|url=https://books.google.com/books?id=aZ4brOPBhXoC&pg=PA191|access-date=8 October 2011|year=2001|publisher=The Electrochemical Society|isbn=978-1-56677-313-3|pages=191–}}

{{cite book|author=E. S. Machlin|title=Materials Science in Microelectronics: The effects of structure on properties in thin films|url=https://books.google.com/books?id=uZNZEgzJltoC&pg=PA36|access-date=8 October 2011|date=9 December 2005|publisher=Elsevier|isbn=978-0-08-044639-4|pages=36–}}

{{cite journal|url=http://www.minsocam.org/msa/ammin/toc/Articles_Free/1997/Rubin_p1001-1006_97.pdf|journal=American Mineralogist|author=A. E. Rubin|title=Sinoite (Si₂N₂O): Crystallization from EL chondrite impact melts|volume=82|page=1001|year=1997|issue=9–10|doi=10.2138/am-1997-9-1016|bibcode=1997AmMin..82.1001R|s2cid=128629202}}

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Category:Ceramic materials

Category:Nitrides

Category:Oxides

Category:Silicon compounds