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	{{Chembox		{{Chembox
	\| Verifiedfields = changed		\| Verifiedfields = changed
	\| verifiedrevid = ~~464361931~~		\| verifiedrevid = 476995335
	\| PIN = Silicon monoxide		\| PIN = Silicon monoxide
			\| ImageFile = Silicon monoxide.jpg
	\| Section1 = {{Chembox Identifiers
			\|ImageFile2=Silicon-monoxide-3D-balls.png
	\| InChI = 1/OSi/c1-2
			\|Section1={{Chembox Identifiers
			\| InChI = 1/OSi/c1-2
	\| InChIKey = LIVNPJMFVYWSIS-UHFFFAOYAO		\| InChIKey = LIVNPJMFVYWSIS-UHFFFAOYAO
	\| InChI1 = 1S/OSi/c1-2		\| InChI1 = 1S/OSi/c1-2
	\| InChIKey1 = LIVNPJMFVYWSIS-UHFFFAOYSA-N		\| InChIKey1 = LIVNPJMFVYWSIS-UHFFFAOYSA-N
	\| CASNo = 10097-28-6		\| CASNo = 10097-28-6
	\| CASNo_Ref = {{cascite\|correct\|CAS}}		\| CASNo_Ref = {{cascite\|correct\|CAS}}
			\| UNII_Ref = {{fdacite\|correct\|FDA}}
	\| PubChem = 66241
			\| UNII = 1OQN9CBG7L
	\| PubChem_Ref = {{Pubchemcite \| correct \| PubChem}}
	\| ~~ChemSpiderID~~ = ~~59626~~		\| PubChem = 66241
			\| ChemSpiderID = 59626
	\| ChemSpiderID_Ref = {{chemspidercite\|correct\|chemspider}}
			\| ChemSpiderID_Ref = {{chemspidercite\|correct\|chemspider}}
	\| EINECS = 233-232-8
	\| MeSHName = Silicon+monoxide		\| EINECS = 233-232-8
			\| MeSHName = Silicon+monoxide
	\| ChEBI_Ref = {{ebicite\|correct\|EBI}}		\| ChEBI_Ref = {{ebicite\|correct\|EBI}}
	\| ChEBI = 30588		\| ChEBI = 30588
	\| SMILES = #		\| SMILES = #
	\| StdInChI_Ref = {{stdinchicite\|changed\|chemspider}}		\| StdInChI_Ref = {{stdinchicite\|changed\|chemspider}}
	\| StdInChI = 1S/H3OSi/c1-2/h2H3		\| StdInChI = 1S/H3OSi/c1-2/h2H3
	\| StdInChIKey_Ref = {{stdinchicite\|changed\|chemspider}}		\| StdInChIKey_Ref = {{stdinchicite\|changed\|chemspider}}
	\| StdInChIKey = UXMAWJKSGBRJKV-UHFFFAOYSA-N		\| StdInChIKey = UXMAWJKSGBRJKV-UHFFFAOYSA-N
	\| Gmelin = 382}}		\| Gmelin = 382
	\| Section2 = {{Chembox Properties
	\| Formula = SiO
	\| MolarMass = 44.08 g/mol
	\| Appearance = brown-black glassy solid
	\| Density = 2.13 g/cm<sup>3</sup>
	\| MeltingPtC = 1702
	\| BoilingPtC = 1880
	\| Solubility = insoluble
	}}		}}
	\| ~~Section7~~ = {{Chembox ~~Hazards~~		\|Section2={{Chembox Properties
	\| ~~ExternalMSDS~~ =		\| Formula = SiO
	\| ~~EUIndex~~ = ~~Not~~ ~~listed~~		\| MolarMass = 44.08 g/mol
			\| Appearance = brown-black glassy solid
	\| EUClass =
			\| Density = 2.13 g/cm<sup>3</sup>
	\| RPhrases =
	\| ~~SPhrases~~ =		\| MeltingPtC = 1702
			\| BoilingPtC = 1880
	\| MainHazards =
	\| ~~NFPA-H~~ = 1		\| Solubility = insoluble
	\| NFPA-F = 0
	\| NFPA-R = 0
	\| NFPA-O =
	\| FlashPt = Non-flammable
	}}		}}
	\| ~~Section8~~ = {{Chembox ~~Related~~		\|Section7={{Chembox Hazards
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	\| OtherAnions = ]<br />]<br />]
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	\| Function = ] ]s
	\| ~~OtherCpds~~ =		\| MainHazards =
			\| NFPA-H = 1
			\| NFPA-F = 0
			\| NFPA-R = 0
			\| NFPA-S =
			\| FlashPt = Non-flammable
			}}
			\|Section8={{Chembox Related
			\| OtherAnions = ]<br />]<br />]
			\| OtherCations = ]<br />]<br />]<br />]
			\| OtherFunction = ]
			\| OtherFunction_label = ] ]s
			\| OtherCompounds =
	}}		}}
	}}		}}
	'''Silicon monoxide''' is the chemical compound with the formula SiO. In the vapour phase it is a diatomic molecule.<ref name="Wiberg&Holleman">{{Holleman&Wiberg}}</ref> It has been detected in stellar objects<ref>Gibb, A.G.; Davis, C.J.; Moore, T.J.T., A survey of SiO 5 → 4 emission towards outflows from massive young stellar objects. Monthly Notices of the Royal Astronomical Society, 382, 3, 1213-1224. {{doi\|10.1111/j.1365-2966.2007.12455.x}}, {{arXiv\|0709.3088v1}}.</ref> and it has been described as the most common oxide of silicon in the universe.<ref name="Jutzi">Peter Jutzi and Ulrich Schubert (2003) ''Silicon chemistry: from the atom to extended systems''. Wiley-VCH ISBN 3527306471.</ref><br />
	When SiO gas is cooled rapidly it condenses to form a brown/black polymeric ]y material,(SiO)<sub>''n''</sub>, which is available commercially and used to deposit films of SiO. Glassy (SiO)<sub>''n''</sub> is air and moisture sensitive. Its surface readily oxidizes in air at room temperature giving a SiO<sub>2</sub> surface layer that protects the material from further oxidation. However, (SiO)<sub>''n''</sub> irreversibly ] into SiO<sub>2</sub> and Si in a few hours between 400 and 800°C and very rapidly between 1,000 and 1440°C, although the reaction does not go to completion.<ref>W. Hertl and W. W. Pultz, ''J. Am. Ceramic Soc''. Vol. 50, Issue 7, (1967) pp. 378-381.</ref>

			'''Silicon monoxide''' is the chemical compound with the formula SiO where silicon is present in the oxidation state +2. In the vapour phase, it is a diatomic molecule.<ref name="Wiberg&Holleman">{{Holleman&Wiberg}}</ref>
	==Formation of SiO==
			It has been detected in stellar objects<ref>Gibb, A.G.; Davis, C.J.; Moore, T.J.T., A survey of SiO 5 → 4 emission towards outflows from massive young stellar objects. ], 382, 3, 1213-1224. {{doi\|10.1111/j.1365-2966.2007.12455.x}}, {{arXiv\|0709.3088v1}}.</ref> and has been described as the most common ] of silicon in the universe.<ref name="Jutzi">Peter Jutzi and Ulrich Schubert (2003) ''Silicon chemistry: from the atom to extended systems''. Wiley-VCH {{ISBN\|3-527-30647-1}}.</ref>
	The first precise report on the formation of SiO was in 1887<ref name="Vol VI 1947 p. 235">J. W. Mellor "A Comprehensive Treatise on Inorganic and Theoretical Chemistry" Vol VI, Longmans, Green and Co. (1947) p. 235.</ref> by the chemist (1850–1927) at the in Cleveland. Maybery claimed that SiO formed as an amorphous greenish-yellow substance with a vitreous luster when silica was reduced with charcoal in the absence of metals in an electric furnace.<ref>C. F. Maybery ''Amer. Chem. Journ.'' 9, 11, (1887).</ref> The substance was always found at the interface between the charcoal and silica particles. By investigating some of the chemical properties of the substance, its specific gravity, and a combustion analysis, Maybery deduced that the substance must be SiO. The equation representing the partial chemical reduction of SiO<sub>2</sub> with C can be represented as:

			==Solid form==
	:<math>SiO_{2} + C \rightleftharpoons SiO + CO</math>
			When SiO gas is cooled rapidly, it condenses to form a brown/black polymeric ]y material, (SiO)<sub>''n''</sub>, which is available commercially and used to deposit films of SiO. Glassy (SiO)<sub>''n''</sub> is air and moisture sensitive.{{clarify\|date=January 2021}}{{citation needed\|date=January 2021}}

			==Oxidation==
	Complete reduction of SiO<sub>2</sub> with twice the amount of carbon yields elemental silicon and twice the amount of carbon monoxide. In 1890, the German chemist ] (the discoverer of germanium) was the first to attempt to synthesize SiO by heating silicon dioxide with silicon in a combustion furnace.<ref>C. Winkler ''Ber''. 23, (1890) p. 2652.</ref>
			Its surface readily oxidizes in air at ], giving an SiO<sub>2</sub> surface layer that ]. However, (SiO)<sub>''n''</sub> irreversibly ] into SiO<sub>2</sub> and Si in a few hours between 400 °C and 800 °C and very rapidly between 1,000 °C and 1,440 °C, although the reaction does not go to completion.<ref>{{cite journal \| last1=HERTL \| first1=W. \| last2=PULTZ \| first2=W. W. \| title=Disproportionation and Vaporization of Solid Silicon Monoxide \| journal=Journal of the American Ceramic Society \| publisher=Wiley \| volume=50 \| issue=7 \| year=1967 \| issn=0002-7820 \| doi=10.1111/j.1151-2916.1967.tb15135.x \| pages=378–381}}</ref>

			==Production==
	:<math>SiO_{2} + Si \rightleftharpoons 2 SiO</math>
			The first precise report on the formation of SiO was in 1887<ref name="Vol VI 1947 p. 235">J. W. Mellor "A Comprehensive Treatise on Inorganic and Theoretical Chemistry" Vol VI, Longmans, Green and Co. (1947) p. 235.</ref> by the chemist ] (1850–1927) at the ] in ]. Maybery claimed that SiO formed as an amorphous greenish-yellow substance with a vitreous luster when silica was reduced with charcoal in the absence of metals in an electric furnace.<ref>C. F. Maybery ''Amer. Chem. Journ.'' 9, 11, (1887).</ref> The substance was always found at the interface between the charcoal and silica particles.

			By investigating some of the chemical properties of the substance, its specific gravity, and a combustion analysis, Maybery deduced that the substance must be SiO. The equation representing the partial chemical reduction of SiO<sub>2</sub> with C can be represented as:
	However, Winkler was not able to produce the monoxide since the temperature of the mixture was only around 1000°C. The experiment was repeated in 1905 by (1869–1942), a ] engineer. Using an electric furnace, Potter was able to attain a temperature of 1700°C and observe the generation of SiO.<ref name="Vol VI 1947 p. 235"/> also investigated the properties and applications of the solid form of SiO.<ref>U.S. Patent 182,082, July 26, 1905.</ref><ref>E. F. Roeber H. C. Parmelee (Eds.) (1907) p. 442.</ref>

			:{{chem\|SiO\|2}} + {{chem\|C}} ⇌ {{chem\|SiO + CO}}
	Because of the volatility of SiO, silica can be removed from ores or minerals by heating them with silicon to produce gaseous SiO in this manner.<ref name="Wiberg&Holleman" /> However, due to the difficulties associated with accurately measuring its vapor pressure and because of the dependency on the specifics of the experimental design, various values have been reported in the literature for the vapor pressure of SiO (g). For the p<sub>SiO</sub> above molten silicon in a quartz (SiO<sub>2</sub>) crucible at the melting point of silicon, one study yielded a value of 0.002 atm.<ref>"Handbook of Semiconductor Silicon Technology," W. C. O'Mara, R. B. Herring, L. P. Hunt, Noyes Publications (1990), p. 148</ref> For the direct vaporization of pure, amorphous SiO solid, 0.001 atm has been reported.<ref>J. A. Nuth III, F. T. Ferguson, The Astrophysical Journal, 649, 1178-1183 (2006)</ref> For a coating system, at the phase boundary between SiO<sub>2</sub> and a silicide, 0.01 atm was reported.<ref>"High-Temperature Oxidation-Resistant Coatings ," National Academy of Sciences/National Academy of Engineering (1970), p. 40</ref>

			Complete reduction of SiO<sub>2</sub> with twice the amount of carbon yields elemental silicon and twice the amount of carbon monoxide. In 1890, the German chemist ] (the discoverer of germanium) was the first to attempt to synthesize SiO by heating silicon dioxide with silicon in a combustion furnace.<ref>C. Winkler ''Ber''. 23, (1890) p. 2652.</ref>
	Silica itself, or refractories containing SiO<sub>2</sub>, can be reduced with H<sub>2</sub> or CO at high temperatures, e.g.:<ref>Charles A. (2004) Schacht Refractories handbook. CRC Press, ISBN 0824756541.</ref>

			:{{chem\|SiO\|2}} + {{chem\|Si}} ⇌ {{chem\|2 SiO}}
	:<math>SiO_{2}(s) + H_{2}(g) \rightleftharpoons SiO (g) + H_{2}O (g)</math>

			However, Winkler was not able to produce the monoxide since the temperature of the mixture was only around 1000 °C. The experiment was repeated in 1905 by ] (1869–1942), a ] engineer. Using an electric furnace, Potter was able to attain a temperature of 1700 °C and observe the generation of SiO.<ref name="Vol VI 1947 p. 235"/> Potter also investigated the properties and applications of the solid form of SiO.<ref>U.S. Patent 182,082, July 26, 1905.</ref><ref>E. F. Roeber H. C. Parmelee (Eds.) (1907) p. 442.</ref>
	As the SiO product volatilizes off (is removed), the equilibrium shifts to the right, resulting in the continued consumption of SiO<sub>2</sub>. Based on the dependence of the rate of silica weight loss on the gas flow rate normal to the interface, the rate of this reduction appears to be controlled by convective diffusion or mass transfer from the reacting surface.<ref>G. Han; H. Y. Sohn J. Am. Ceram. Soc. 88 882-888 (2005)</ref><ref>R. A. Gardner J. Solid State Chem. 9, 336-344 (1974)</ref>

	==Gaseous ~~(Molecular)~~ ~~SiO~~==		=== Gaseous form ===
			Because of the volatility of SiO, silica can be removed from ores or minerals by heating them with silicon to produce gaseous SiO in this manner.<ref name="Wiberg&Holleman" /> However, due to the difficulties associated with accurately measuring its vapor pressure, and because of the dependency on the specifics of the experimental design, various values have been reported in the literature for the vapor pressure of SiO (g). For the p<sub>SiO</sub> above molten silicon in a quartz (SiO<sub>2</sub>) crucible at the melting point of silicon, one study yielded a value of 0.002 atm.<ref>"Handbook of Semiconductor Silicon Technology," W. C. O'Mara, R. B. Herring, L. P. Hunt, Noyes Publications (1990), p. 148</ref> For the direct vaporization of pure, amorphous SiO solid, 0.001 atm has been reported.<ref>{{cite journal \| last1=Nuth III \| first1=Joseph A. \| last2=Ferguson \| first2=Frank T. \| title=Silicates Do Nucleate in Oxygen-rich Circumstellar Outflows: New Vapor Pressure Data for SiO \| journal=The Astrophysical Journal \| publisher=American Astronomical Society \| volume=649 \| issue=2 \| year=2006 \| issn=0004-637X \| doi=10.1086/506264 \| pages=1178–1183\| bibcode=2006ApJ...649.1178N \| s2cid=123656840 \| doi-access=free }}</ref> For a coating system, at the phase boundary between SiO<sub>2</sub> and a silicide, 0.01 atm was reported.<ref>"High-Temperature Oxidation-Resistant Coatings ," National Academy of Sciences/National Academy of Engineering (1970), p. 40</ref>
	Silicon monoxide molecules have been trapped in an argon matrix cooled by helium. The SiO bond length determined from SiO molecules isolated in argon is between 148.9 pm<ref name="Jutzi" /> and 1.51 pm.<ref name="Inorganic Chemistry 2001 p. 858">Inorganic Chemistry, Holleman-Wiberg, Academci Press (2001) p. 858.</ref> This bond length is similar to the Si=O double bonds (''r''<sub>SiO</sub> = 1.48 pm) in matrix isolated linear, molecular, SiO<sub>2</sub> (O=S=O), indicative of the absence of a triple bond as in ].<ref name="Jutzi" /> However, the SiO triple bond has a calculated bond length of 1.50 pm and a bond energy of 794 kJ/mol, which are also very close to those reported for SiO.<ref name="Inorganic Chemistry 2001 p. 858"/> The SiO double bond structure is, notably, an exception to Lewis' ] for molecules composed of the light main group elements, whereas the SiO triple bond satisfies this rule. That anomaly not withstanding, the observation that monomeric SiO is short-lived and that (SiO)<sub>n</sub> ]s with n = 2,3,4,5 are known, all having closed ring structures in which the silicon atoms are connected through bridging oxygen atoms (i.e. each oxygen atom is singly bonded to two silicon atoms; no Si-Si bonds), suggests the Si=O double bond structure, with a hypovalent silicon atom, is likely for the monomer.<ref name="Jutzi" />

			Silica itself, or refractories containing SiO<sub>2</sub>, can be reduced with H<sub>2</sub> or CO at high temperatures, e.g.:<ref>Charles A. (2004) Schacht Refractories handbook. CRC Press, {{ISBN\|0-8247-5654-1}}.</ref>
	SiO condensed with ], ] or COS, followed by irradiation with light, the planar molecules OSiF<sub>2</sub>,(Si-O 148 pm); OSiCl<sub>2</sub>, (Si-O 149 pm) and linear OSiS (Si-O 149 pm, Si-S 190 pm) are produced.<ref name="Jutzi" />

			:{{chem\|SiO\|2\|(s) + H\|2\|}}(g) ⇌ {{chem\| SiO(g) + H\|2\|O(g)}}
	SiO condensed with oxygen atoms generated by microwave discharge produces molecular SiO<sub>2</sub> which has a linear structure.<br />
	When metal atoms are co-deposited (i.e.: Na, Al, Pd, Ag, Au) triatomic molecules are produced with linear, (AlSiO and PdSiO), non-linear (AgSiO and AuSiO), and ring (NaSiO) structures.<ref name="Jutzi" />

			As the SiO product volatilizes off (is removed), the equilibrium shifts to the right, resulting in the continued consumption of SiO<sub>2</sub>. Based on the dependence of the rate of silica weight loss on the gas flow rate normal to the interface, the rate of this reduction appears to be controlled by convective diffusion or mass transfer from the reacting surface.<ref>{{cite journal \| last1=Han \| first1=Gilsoo \| last2=Sohn \| first2=Hong Yong \| title=Kinetics of the Hydrogen Reduction of Silica Incorporating the Effect of Gas-Volume Change upon Reaction \| journal=Journal of the American Ceramic Society \| publisher=Wiley \| volume=88 \| issue=4 \| year=2005 \| issn=0002-7820 \| doi=10.1111/j.1551-2916.2005.00144.x \| pages=882–888}}</ref><ref>{{cite journal \| last=Gardner \| first=Richard A. \| title=The kinetics of silica reduction in hydrogen \| journal=Journal of Solid State Chemistry \| publisher=Elsevier BV \| volume=9 \| issue=4 \| year=1974 \| issn=0022-4596 \| doi=10.1016/0022-4596(74)90092-9 \| pages=336–344\| bibcode=1974JSSCh...9..336G }}</ref>
	==Solid (Polymeric) SiO==

	Potter reported SiO solid as yellowish-brown in color and as being an electrical and thermal insulator. The solid burns in oxygen and decomposes water with the liberation of hydrogen. It dissolves in warm alkali hydroxides and in hydrofluoric acid. Although Potter reported the heat of combustion of SiO to be 200 to 800 calories higher than that of an equilibrium mixture of Si and SiO<sub>2</sub> (which could, arguably, be used as evidence that SiO is a unique chemical compound),<ref>J. W. Mellor "A Comprehensive Treatise on Inorganic and Theoretical Chemistry" Vol VI, Longmans, Green and Co. (1947) p. 234.</ref> recent microscopy and spectroscopy studies suggest that amorphous solid SiO is best considered as an inhomogeneous mixture of amorphous ] and amorphous ] with some chemical bonding at the interface of the Si and SiO<sub>2</sub> phases.<ref>Friede B., Jansen M. (1996) Some comments on so-called silicon monoxide. Journal of Non-Crystalline Solids, 204, 2, 202-203. {{doi\|10.1016/S0022-3093(96)00555-8}}.</ref><ref>Schulmeister K. and Mader W. (2003) TEM investigation on the structure of amorphous silicon monoxide. Journal of Non-Crystalline Solids, 320, 1-3, 143-150. {{doi\|10.1016/S0022-3093(03)00029-2}}.</ref>
			==Gaseous (molecular) form==
			Silicon monoxide molecules have been trapped in an argon matrix cooled by helium. In these conditions, the SiO bond length is between 148.9 pm<ref name="Jutzi" /> and 151 pm.<ref name="Inorganic Chemistry 2001 p. 858">Inorganic Chemistry, Holleman-Wiberg, Academic Press (2001) p. 858.</ref> This bond length is similar to the length of Si=O double bonds (148 pm) in the matrix-isolated linear molecule {{chem\|SiO\|2}} (O=Si=O), suggestive of the absence of a triple bond as in ].<ref name="Jutzi" /> However, the SiO triple bond has a calculated bond length of 150 pm and a bond energy of 794 kJ/mol, which are also very close to those reported for SiO.<ref name="Inorganic Chemistry 2001 p. 858"/> In the carbon analogues the formal double bonds of ] (116 pm) is also close to the triple bond length of ] (112.8 pm); in light of this the observed bond length of SiO may be consistent with at least some triple-bond character in the diatomic molecule. The SiO double bond structure is, notably, an exception to Lewis' ] for molecules composed of the light main group elements, whereas the SiO triple bond satisfies this rule. That anomaly not withstanding, the observation that monomeric SiO is short-lived and that (SiO)<sub>'n'</sub> ]s with 'n' = 2,3,4,5 are known,<ref>{{Cite journal\|last1=Chrystie\|first1=Robin S. M.\|last2=Janbazi\|first2=Hossein\|last3=Dreier\|first3=Thomas\|last4=Wiggers\|first4=Hartmut\|last5=Wlokas\|first5=Irenäus\|last6=Schulz\|first6=Christof\|date=2019-01-01\|title=Comparative study of flame-based SiO2 nanoparticle synthesis from TMS and HMDSO: SiO-LIF concentration measurement and detailed simulation\|journal=Proceedings of the Combustion Institute\|volume=37\|issue=1\|pages=1221–1229\|doi=10.1016/j.proci.2018.07.024\|s2cid=139291303 \|issn=1540-7489}}</ref> all having closed ring structures in which the silicon atoms are connected through bridging oxygen atoms (i.e. each oxygen atom is singly bonded to two silicon atoms; no Si-Si bonds), suggests the Si=O double bond structure, with a hypovalent silicon atom, is likely for the monomer.<ref name="Jutzi" />

			Condensing molecular SiO in argon matrix together with ], ] or ] (COS), followed by irradiation with light, produces the planar molecules {{chem\|OSiF\|2}} (with Si-O distance 148 pm) and {{chem\|OSiCl\|2}} (Si-O 149 pm), and the linear molecule {{chem\|OSiS}} (Si-O 149 pm, Si-S 190 pm).<ref name="Jutzi" />

			Matrix-isolated molecular SiO reacts with oxygen atoms generated by microwave discharge to produce molecular {{chem\|SiO\|2}} which has a linear structure.

			When metal atoms (such as ], ], ], ], and ]) are co-deposited with SiO, triatomic molecules are produced with linear (AlSiO and PdSiO), non-linear (AgSiO and AuSiO), and ring (NaSiO) structures.<ref name="Jutzi" />

			==Solid (polymeric) form==
			Potter reported SiO solid as yellowish-brown in color and as being an electrical and thermal insulator. The solid burns in oxygen and decomposes water with the liberation of hydrogen. It dissolves in warm alkali hydroxides and in hydrofluoric acid. Even though Potter reported the heat of combustion of SiO to be 200 to 800 calories higher than that of an equilibrium mixture of Si and SiO<sub>2</sub> (which could, arguably, be used as evidence that SiO is a unique chemical compound),<ref>J. W. Mellor "A Comprehensive Treatise on Inorganic and Theoretical Chemistry" Vol VI, Longmans, Green and Co. (1947) p. 234.</ref> some studies characterized commercially available solid silicon monoxide materials as an inhomogeneous mixture of amorphous ] and amorphous ] with some chemical bonding at the interface of the Si and SiO<sub>2</sub> phases.<ref>Friede B., Jansen M. (1996) Some comments on so-called silicon monoxide. Journal of Non-Crystalline Solids, 204, 2, 202-203. {{doi\|10.1016/S0022-3093(96)00555-8}}.</ref><ref>Schulmeister K. and Mader W. (2003) TEM investigation on the structure of amorphous silicon monoxide. Journal of Non-Crystalline Solids, 320, 1-3, 143-150. {{doi\|10.1016/S0022-3093(03)00029-2}}.</ref> Recent spectroscopic studies in a correlation with Potter's report suggest that commercially available solid silicon monoxide materials can not be considered as an inhomogeneous mixture of amorphous ] and amorphous ].<ref>Gunduz, D. C., Tankut, A., Sedani, S., Karaman, M. and Turan, R. (2015) Crystallization and phase separation mechanism of silicon oxide thin films fabricated via e-beam evaporation of silicon monoxide. Phys. Status Solidi C, 12: 1229–1235. {{doi\|10.1002/pssc.201510114}}.
			</ref>

			== Interstellar occurrence ==
			Interstellar SiO was first reported in 1971 after detection in the giant molecular cloud ].<ref>{{Cite journal\|last1=Wilson\|first1=R. W.\|last2=Penzias\|first2=A. A.\|last3=Jefferts\|first3=K. B.\|last4=Kutner\|first4=M.\|last5=Thaddeus\|first5=P.\|date=1971\|title=Discovery of Interstellar Silicon Monoxide\|journal=The Astrophysical Journal\|language=en\|volume=167\|pages=L97\|doi=10.1086/180769\|bibcode=1971ApJ...167L..97W\|issn=0004-637X\|doi-access=free}}</ref> SiO is used as a molecular tracer of shocked gas in ] outflows.<ref>{{Cite journal\|last1=Martin-Pintado\|first1=J.\|last2=Bachiller\|first2=R.\|last3=Fuente\|first3=A.\|date=1992-02-01\|title=SIO Emission as a Tracer of Shocked Gas in Molecular Outflows\|url=http://adsabs.harvard.edu/abs/1992A%26A...254..315M\|journal=Astronomy and Astrophysics\|volume=254\|pages=315\|bibcode=1992A&A...254..315M\|issn=0004-6361}}</ref>

	==References==		==References==
	{{~~reflist~~}}		{{Reflist}}
			{{Molecules detected in outer space}}
			{{silicon compounds}}
			{{Oxides}}
			{{Authority control}}

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Latest revision as of 12:03, 7 January 2024

Silicon monoxide
Names


Preferred IUPAC name Silicon monoxide
Identifiers
CAS Number	10097-28-6
3D model (JSmol)	Interactive image
ChEBI	CHEBI:30588
ChemSpider	59626
ECHA InfoCard	100.030.198
EC Number	233-232-8
Gmelin Reference	382
MeSH	Silicon+monoxide
PubChem CID	66241
UNII	1OQN9CBG7L
CompTox Dashboard (EPA)	DTXSID7064940
InChI InChI=1S/H3OSi/c1-2/h2H3Key: UXMAWJKSGBRJKV-UHFFFAOYSA-N InChI=1/OSi/c1-2Key: LIVNPJMFVYWSIS-UHFFFAOYAO InChI=1S/OSi/c1-2Key: LIVNPJMFVYWSIS-UHFFFAOYSA-N
SMILES #
Properties
Chemical formula	SiO
Molar mass	44.08 g/mol
Appearance	brown-black glassy solid
Density	2.13 g/cm
Melting point	1,702 °C (3,096 °F; 1,975 K)
Boiling point	1,880 °C (3,420 °F; 2,150 K)
Solubility in water	insoluble
Hazards
NFPA 704 (fire diamond)	1 0 0
Flash point	Non-flammable
Related compounds
Other anions	Silicon sulfide Silicon selenide Silicon telluride
Other cations	Carbon monoxide Germanium(II) oxide Tin(II) oxide Lead(II) oxide
Related silicon oxides	Silicon dioxide
Except where otherwise noted, data are given for materials in their standard state (at 25 °C , 100 kPa). N verify (what is ?) Infobox references

Chemical compound

Silicon monoxide is the chemical compound with the formula SiO where silicon is present in the oxidation state +2. In the vapour phase, it is a diatomic molecule. It has been detected in stellar objects and has been described as the most common oxide of silicon in the universe.

Solid form

When SiO gas is cooled rapidly, it condenses to form a brown/black polymeric glassy material, (SiO)_n, which is available commercially and used to deposit films of SiO. Glassy (SiO)_n is air and moisture sensitive.

Oxidation

Its surface readily oxidizes in air at room temperature, giving an SiO₂ surface layer that protects the material from further oxidation. However, (SiO)_n irreversibly disproportionates into SiO₂ and Si in a few hours between 400 °C and 800 °C and very rapidly between 1,000 °C and 1,440 °C, although the reaction does not go to completion.

Production

The first precise report on the formation of SiO was in 1887 by the chemist Charles F. Maybery (1850–1927) at the Case School of Applied Science in Cleveland. Maybery claimed that SiO formed as an amorphous greenish-yellow substance with a vitreous luster when silica was reduced with charcoal in the absence of metals in an electric furnace. The substance was always found at the interface between the charcoal and silica particles.

By investigating some of the chemical properties of the substance, its specific gravity, and a combustion analysis, Maybery deduced that the substance must be SiO. The equation representing the partial chemical reduction of SiO₂ with C can be represented as:

SiO
₂ + C ⇌ SiO + CO

Complete reduction of SiO₂ with twice the amount of carbon yields elemental silicon and twice the amount of carbon monoxide. In 1890, the German chemist Clemens Winkler (the discoverer of germanium) was the first to attempt to synthesize SiO by heating silicon dioxide with silicon in a combustion furnace.

SiO
₂ + Si ⇌ 2 SiO

However, Winkler was not able to produce the monoxide since the temperature of the mixture was only around 1000 °C. The experiment was repeated in 1905 by Henry Noel Potter (1869–1942), a Westinghouse engineer. Using an electric furnace, Potter was able to attain a temperature of 1700 °C and observe the generation of SiO. Potter also investigated the properties and applications of the solid form of SiO.

Gaseous form

Because of the volatility of SiO, silica can be removed from ores or minerals by heating them with silicon to produce gaseous SiO in this manner. However, due to the difficulties associated with accurately measuring its vapor pressure, and because of the dependency on the specifics of the experimental design, various values have been reported in the literature for the vapor pressure of SiO (g). For the p_SiO above molten silicon in a quartz (SiO₂) crucible at the melting point of silicon, one study yielded a value of 0.002 atm. For the direct vaporization of pure, amorphous SiO solid, 0.001 atm has been reported. For a coating system, at the phase boundary between SiO₂ and a silicide, 0.01 atm was reported.

Silica itself, or refractories containing SiO₂, can be reduced with H₂ or CO at high temperatures, e.g.:

SiO
₂(s) + H
₂(g) ⇌ SiO(g) + H
₂O(g)

As the SiO product volatilizes off (is removed), the equilibrium shifts to the right, resulting in the continued consumption of SiO₂. Based on the dependence of the rate of silica weight loss on the gas flow rate normal to the interface, the rate of this reduction appears to be controlled by convective diffusion or mass transfer from the reacting surface.

Gaseous (molecular) form

Silicon monoxide molecules have been trapped in an argon matrix cooled by helium. In these conditions, the SiO bond length is between 148.9 pm and 151 pm. This bond length is similar to the length of Si=O double bonds (148 pm) in the matrix-isolated linear molecule SiO
₂ (O=Si=O), suggestive of the absence of a triple bond as in carbon monoxide. However, the SiO triple bond has a calculated bond length of 150 pm and a bond energy of 794 kJ/mol, which are also very close to those reported for SiO. In the carbon analogues the formal double bonds of carbon dioxide (116 pm) is also close to the triple bond length of carbon monoxide (112.8 pm); in light of this the observed bond length of SiO may be consistent with at least some triple-bond character in the diatomic molecule. The SiO double bond structure is, notably, an exception to Lewis' octet rule for molecules composed of the light main group elements, whereas the SiO triple bond satisfies this rule. That anomaly not withstanding, the observation that monomeric SiO is short-lived and that (SiO)_'n' oligomers with 'n' = 2,3,4,5 are known, all having closed ring structures in which the silicon atoms are connected through bridging oxygen atoms (i.e. each oxygen atom is singly bonded to two silicon atoms; no Si-Si bonds), suggests the Si=O double bond structure, with a hypovalent silicon atom, is likely for the monomer.

Condensing molecular SiO in argon matrix together with fluorine, chlorine or carbonyl sulfide (COS), followed by irradiation with light, produces the planar molecules OSiF
₂ (with Si-O distance 148 pm) and OSiCl
₂ (Si-O 149 pm), and the linear molecule OSiS (Si-O 149 pm, Si-S 190 pm).

Matrix-isolated molecular SiO reacts with oxygen atoms generated by microwave discharge to produce molecular SiO
₂ which has a linear structure.

When metal atoms (such as Na, Al, Pd, Ag, and Au) are co-deposited with SiO, triatomic molecules are produced with linear (AlSiO and PdSiO), non-linear (AgSiO and AuSiO), and ring (NaSiO) structures.

Solid (polymeric) form

Potter reported SiO solid as yellowish-brown in color and as being an electrical and thermal insulator. The solid burns in oxygen and decomposes water with the liberation of hydrogen. It dissolves in warm alkali hydroxides and in hydrofluoric acid. Even though Potter reported the heat of combustion of SiO to be 200 to 800 calories higher than that of an equilibrium mixture of Si and SiO₂ (which could, arguably, be used as evidence that SiO is a unique chemical compound), some studies characterized commercially available solid silicon monoxide materials as an inhomogeneous mixture of amorphous SiO₂ and amorphous Si with some chemical bonding at the interface of the Si and SiO₂ phases. Recent spectroscopic studies in a correlation with Potter's report suggest that commercially available solid silicon monoxide materials can not be considered as an inhomogeneous mixture of amorphous SiO₂ and amorphous Si.

Interstellar occurrence

Interstellar SiO was first reported in 1971 after detection in the giant molecular cloud Sgr B2. SiO is used as a molecular tracer of shocked gas in protostellar outflows.

References

^ Holleman, Arnold Frederik; Wiberg, Egon (2001), Wiberg, Nils (ed.), Inorganic Chemistry, translated by Eagleson, Mary; Brewer, William, San Diego/Berlin: Academic Press/De Gruyter, ISBN 0-12-352651-5
Gibb, A.G.; Davis, C.J.; Moore, T.J.T., A survey of SiO 5 → 4 emission towards outflows from massive young stellar objects. Monthly Notices of the Royal Astronomical Society, 382, 3, 1213-1224. doi:10.1111/j.1365-2966.2007.12455.x, arXiv:0709.3088v1.
^ Peter Jutzi and Ulrich Schubert (2003) Silicon chemistry: from the atom to extended systems. Wiley-VCH ISBN 3-527-30647-1.
HERTL, W.; PULTZ, W. W. (1967). "Disproportionation and Vaporization of Solid Silicon Monoxide". Journal of the American Ceramic Society. 50 (7). Wiley: 378–381. doi:10.1111/j.1151-2916.1967.tb15135.x. ISSN 0002-7820.
^ J. W. Mellor "A Comprehensive Treatise on Inorganic and Theoretical Chemistry" Vol VI, Longmans, Green and Co. (1947) p. 235.
C. F. Maybery Amer. Chem. Journ. 9, 11, (1887).
C. Winkler Ber. 23, (1890) p. 2652.
U.S. Patent 182,082, July 26, 1905.
E. F. Roeber H. C. Parmelee (Eds.) Electrochemical and Metallurgical Industry, Vol. 5 (1907) p. 442.
"Handbook of Semiconductor Silicon Technology," W. C. O'Mara, R. B. Herring, L. P. Hunt, Noyes Publications (1990), p. 148
Nuth III, Joseph A.; Ferguson, Frank T. (2006). "Silicates Do Nucleate in Oxygen-rich Circumstellar Outflows: New Vapor Pressure Data for SiO". The Astrophysical Journal. 649 (2). American Astronomical Society: 1178–1183. Bibcode:2006ApJ...649.1178N. doi:10.1086/506264. ISSN 0004-637X. S2CID 123656840.
"High-Temperature Oxidation-Resistant Coatings ," National Academy of Sciences/National Academy of Engineering (1970), p. 40
Charles A. (2004) Schacht Refractories handbook. CRC Press, ISBN 0-8247-5654-1.
Han, Gilsoo; Sohn, Hong Yong (2005). "Kinetics of the Hydrogen Reduction of Silica Incorporating the Effect of Gas-Volume Change upon Reaction". Journal of the American Ceramic Society. 88 (4). Wiley: 882–888. doi:10.1111/j.1551-2916.2005.00144.x. ISSN 0002-7820.
Gardner, Richard A. (1974). "The kinetics of silica reduction in hydrogen". Journal of Solid State Chemistry. 9 (4). Elsevier BV: 336–344. Bibcode:1974JSSCh...9..336G. doi:10.1016/0022-4596(74)90092-9. ISSN 0022-4596.
^ Inorganic Chemistry, Holleman-Wiberg, Academic Press (2001) p. 858.
Chrystie, Robin S. M.; Janbazi, Hossein; Dreier, Thomas; Wiggers, Hartmut; Wlokas, Irenäus; Schulz, Christof (2019-01-01). "Comparative study of flame-based SiO2 nanoparticle synthesis from TMS and HMDSO: SiO-LIF concentration measurement and detailed simulation". Proceedings of the Combustion Institute. 37 (1): 1221–1229. doi:10.1016/j.proci.2018.07.024. ISSN 1540-7489. S2CID 139291303.
J. W. Mellor "A Comprehensive Treatise on Inorganic and Theoretical Chemistry" Vol VI, Longmans, Green and Co. (1947) p. 234.
Friede B., Jansen M. (1996) Some comments on so-called silicon monoxide. Journal of Non-Crystalline Solids, 204, 2, 202-203. doi:10.1016/S0022-3093(96)00555-8.
Schulmeister K. and Mader W. (2003) TEM investigation on the structure of amorphous silicon monoxide. Journal of Non-Crystalline Solids, 320, 1-3, 143-150. doi:10.1016/S0022-3093(03)00029-2.
Gunduz, D. C., Tankut, A., Sedani, S., Karaman, M. and Turan, R. (2015) Crystallization and phase separation mechanism of silicon oxide thin films fabricated via e-beam evaporation of silicon monoxide. Phys. Status Solidi C, 12: 1229–1235. doi:10.1002/pssc.201510114.
Wilson, R. W.; Penzias, A. A.; Jefferts, K. B.; Kutner, M.; Thaddeus, P. (1971). "Discovery of Interstellar Silicon Monoxide". The Astrophysical Journal. 167: L97. Bibcode:1971ApJ...167L..97W. doi:10.1086/180769. ISSN 0004-637X.
Martin-Pintado, J.; Bachiller, R.; Fuente, A. (1992-02-01). "SIO Emission as a Tracer of Shocked Gas in Molecular Outflows". Astronomy and Astrophysics. 254: 315. Bibcode:1992A&A...254..315M. ISSN 0004-6361.

Molecules detected in outer space

Molecules

Diatomic	Aluminium monochloride Aluminium monofluoride Aluminium(II) oxide Argonium Carbon cation Carbon monophosphide Carbon monosulfide Carbon monoxide Cyano radical Diatomic carbon Fluoromethylidynium Helium hydride ion Hydrogen chloride Hydrogen fluoride Hydrogen (molecular) Hydroxyl radical Iron(II) oxide Magnesium monohydride Methylidyne radical Nitric oxide Nitrogen (molecular) Imidogen Sulfur mononitride Oxygen (molecular) Phosphorus monoxide Phosphorus mononitride Potassium chloride Silicon carbide Silicon monoxide Silicon monosulfide Sodium chloride Sodium iodide Sulfanyl Sulfur monoxide Titanium(II) oxide
Triatomic	Aluminium(I) hydroxide Aluminium isocyanide Amino radical Carbon dioxide Carbonyl sulfide CCP radical Chloronium Diazenylium Dicarbon monoxide Disilicon carbide Ethynyl radical Formyl radical Hydrogen cyanide (HCN) Hydrogen isocyanide (HNC) Hydrogen sulfide Hydroperoxyl Iron cyanide Isoformyl Magnesium cyanide Magnesium isocyanide Methylene N₂H Nitrous oxide Nitroxyl Ozone Methylidynephosphane Potassium cyanide Trihydrogen cation Sodium cyanide Sodium hydroxide Silicon carbonitride c-Silicon dicarbide SiNC Sulfur dioxide Thioformyl Thioxoethenylidene Titanium dioxide Tricarbon Water
Four atoms	Acetylene Ammonia Isocyanic acid Cyanoethynyl Formaldehyde Fulminic acid HCCN Hydrogen peroxide Hydromagnesium isocyanide Isocyanic acid Isothiocyanic acid Ketenyl Methylene amidogen Methyl cation Methyl radical Propynylidyne Protonated carbon dioxide Protonated hydrogen cyanide Silicon tricarbide Thioformaldehyde Tricarbon monoxide Tricarbon monosulfide Thiocyanic acid
Five atoms	Ammonium ion Butadiynyl Carbodiimide Cyanamide Cyanoacetylene Cyanoformaldehyde Cyanomethyl Cyclopropenylidene Formic acid Isocyanoacetylene Ketene Methane Methoxy radical Methylenimine Propadienylidene Protonated formaldehyde Silane Silicon-carbide cluster
Six atoms	Acetonitrile Cyanobutadiynyl radical E-Cyanomethanimine Cyclopropenone Diacetylene Ethylene Formamide HC₄N Ketenimine Methanethiol Methanol Methyl isocyanide Pentynylidyne Propynal Protonated cyanoacetylene
Seven atoms	Acetaldehyde Acrylonitrile Vinyl cyanide Cyanodiacetylene Ethylene oxide Glycolonitrile Hexatriynyl radical Propyne Methylamine Methyl isocyanate Vinyl alcohol
Eight atoms	Acetic acid Aminoacetonitrile Cyanoallene Ethanimine Glycolaldehyde Hexapentaenylidene Methylcyanoacetylene Methyl formate Acrolein
Nine atoms	Acetamide Cyanohexatriyne Dimethyl ether Ethanol Methyldiacetylene Octatetraynyl radical Propene Ethanethiol Propionitrile N-Methylformamide
Ten atoms or more	Acetone Benzene Benzonitrile Buckminsterfullerene (C₆₀, C₆₀, fullerene, buckyball) C₇₀ fullerene Cyanodecapentayne Ethylene glycol Ethyl formate Methyl acetate Methyl-cyano-diacetylene Methyltriacetylene Propionaldehyde Butyronitrile Pyrimidine Heptatrienyl radical

Deuterated
molecules

Unconfirmed

v t e Silicon compounds
Si(II)	SiO SiS
Si(III)	Si₂H₆ Si₂Cl₆
Si(IV)	SiBr₄ SiC SiCl₄ SiF₄ SiH₄ SiI₄ SiAu₄ SiO₂ SiS₂ Si₃N₄ Si(N₃)₄ Si₂N₂O Si₂Cl₆O SiF₃Cl

v t e Oxides
Mixed oxidation states	Antimony tetroxide (Sb₂O₄) Boron suboxide (B₁₂O₂) Carbon suboxide (C₃O₂) Chlorine perchlorate (Cl₂O₄) Chloryl perchlorate (Cl₂O₆) Cobalt(II,III) oxide (Co₃O₄) Dichlorine pentoxide (Cl₂O₅) Iron(II,III) oxide (Fe₃O₄) Lead(II,IV) oxide (Pb₃O₄) Manganese(II,III) oxide (Mn₃O₄) Mellitic anhydride (C₁₂O₉) Praseodymium(III,IV) oxide (Pr₆O₁₁) Silver(I,III) oxide (Ag₂O₂) Terbium(III,IV) oxide (Tb₄O₇) Tribromine octoxide (Br₃O₈) Triuranium octoxide (U₃O₈)
+1 oxidation state	Aluminium(I) oxide (Al₂O) Copper(I) oxide (Cu₂O) Caesium monoxide (Cs₂O) Dibromine monoxide (Br₂O) Dicarbon monoxide (C₂O) Dichlorine monoxide (Cl₂O) Gallium(I) oxide (Ga₂O) Iodine(I) oxide (I₂O) Lithium oxide (Li₂O) Mercury(I) oxide (Hg₂O) Nitrous oxide (N₂O) Potassium oxide (K₂O) Rubidium oxide (Rb₂O) Silver oxide (Ag₂O) Thallium(I) oxide (Tl₂O) Sodium oxide (Na₂O) Water (hydrogen oxide) (H₂O)
+2 oxidation state	Aluminium(II) oxide (AlO) Barium oxide (BaO) Berkelium monoxide (BkO) Beryllium oxide (BeO) Boron monoxide (BO) Bromine monoxide (BrO) Cadmium oxide (CdO) Calcium oxide (CaO) Carbon monoxide (CO) Chlorine monoxide (ClO) Chromium(II) oxide (CrO) Cobalt(II) oxide (CoO) Copper(II) oxide (CuO) Dinitrogen dioxide (N₂O₂) Europium(II) oxide (EuO) Germanium monoxide (GeO) Iron(II) oxide (FeO) Iodine monoxide (IO) Lead(II) oxide (PbO) Magnesium oxide (MgO) Manganese(II) oxide (MnO) Mercury(II) oxide (HgO) Nickel(II) oxide (NiO) Nitric oxide (NO) Niobium monoxide (NbO) Palladium(II) oxide (PdO) Phosphorus monoxide (PO) Polonium monoxide (PoO) Protactinium monoxide (PaO) Radium oxide (RaO) Silicon monoxide (SiO) Strontium oxide (SrO) Sulfur monoxide (SO) Disulfur dioxide (S₂O₂) Thorium monoxide (ThO) Tin(II) oxide (SnO) Titanium(II) oxide (TiO) Vanadium(II) oxide (VO) Yttrium(II) oxide (YO) Zirconium monoxide (ZrO) Zinc oxide (ZnO)
+3 oxidation state	Actinium(III) oxide (Ac₂O₃) Aluminium oxide (Al₂O₃) Americium(III) oxide (Am₂O₃) Antimony trioxide (Sb₂O₃) Arsenic trioxide (As₂O₃) Berkelium(III) oxide (Bk₂O₃) Bismuth(III) oxide (Bi₂O₃) Boron trioxide (B₂O₃) Caesium sesquioxide (Cs₂O₃) Californium(III) oxide (Cf₂O₃) Cerium(III) oxide (Ce₂O₃) Chromium(III) oxide (Cr₂O₃) Cobalt(III) oxide (Co₂O₃) Dinitrogen trioxide (N₂O₃) Dysprosium(III) oxide (Dy₂O₃) Einsteinium(III) oxide (Es₂O₃) Erbium(III) oxide (Er₂O₃) Europium(III) oxide (Eu₂O₃) Gadolinium(III) oxide (Gd₂O₃) Gallium(III) oxide (Ga₂O₃) Gold(III) oxide (Au₂O₃) Holmium(III) oxide (Ho₂O₃) Indium(III) oxide (In₂O₃) Iron(III) oxide (Fe₂O₃) Lanthanum oxide (La₂O₃) Lutetium(III) oxide (Lu₂O₃) Manganese(III) oxide (Mn₂O₃) Neodymium(III) oxide (Nd₂O₃) Nickel(III) oxide (Ni₂O₃) Phosphorus trioxide (P₄O₆) Praseodymium(III) oxide (Pr₂O₃) Promethium(III) oxide (Pm₂O₃) Rhodium(III) oxide (Rh₂O₃) Samarium(III) oxide (Sm₂O₃) Scandium oxide (Sc₂O₃) Terbium(III) oxide (Tb₂O₃) Thallium(III) oxide (Tl₂O₃) Thulium(III) oxide (Tm₂O₃) Titanium(III) oxide (Ti₂O₃) Tungsten(III) oxide (W₂O₃) Vanadium(III) oxide (V₂O₃) Ytterbium(III) oxide (Yb₂O₃) Yttrium(III) oxide (Y₂O₃)
+4 oxidation state	Americium dioxide (AmO₂) Berkelium(IV) oxide (BkO₂) Bromine dioxide (BrO₂) Californium dioxide (CfO₂) Carbon dioxide (CO₂) Carbon trioxide (CO₃) Cerium(IV) oxide (CeO₂) Chlorine dioxide (ClO₂) Chromium(IV) oxide (CrO₂) Curium(IV) oxide (CmO₂) Dinitrogen tetroxide (N₂O₄) Germanium dioxide (GeO₂) Iodine dioxide (IO₂) Iridium dioxide (IrO₂) Hafnium(IV) oxide (HfO₂) Lead dioxide (PbO₂) Manganese dioxide (MnO₂) Molybdenum dioxide (MoO₂) Neptunium(IV) oxide (NpO₂) Nitrogen dioxide (NO₂) Niobium dioxide (NbO₂) Osmium dioxide (OsO₂) Platinum dioxide (PtO₂) Plutonium(IV) oxide (PuO₂) Polonium dioxide (PoO₂) Praseodymium(IV) oxide (PrO₂) Protactinium(IV) oxide (PaO₂) Rhenium(IV) oxide (ReO₂) Rhodium(IV) oxide (RhO₂) Ruthenium(IV) oxide (RuO₂) Selenium dioxide (SeO₂) Silicon dioxide (SiO₂) Sulfur dioxide (SO₂) Technetium(IV) oxide (TcO₂) Tellurium dioxide (TeO₂) Terbium(IV) oxide (TbO₂) Thorium dioxide (ThO₂) Tin dioxide (SnO₂) Titanium dioxide (TiO₂) Tungsten(IV) oxide (WO₂) Uranium dioxide (UO₂) Vanadium(IV) oxide (VO₂) Zirconium dioxide (ZrO₂)
+5 oxidation state	Antimony pentoxide (Sb₂O₅) Arsenic pentoxide (As₂O₅) Bismuth pentoxide (Bi₂O₅) Dinitrogen pentoxide (N₂O₅) Niobium pentoxide (Nb₂O₅) Phosphorus pentoxide (P₂O₅) Protactinium(V) oxide (Pa₂O₅) Tantalum pentoxide (Ta₂O₅) Tungsten pentoxide (W₂O₅) Vanadium(V) oxide (V₂O₅)
+6 oxidation state	Chromium trioxide (CrO₃) Molybdenum trioxide (MoO₃) Polonium trioxide (PoO₃) Rhenium trioxide (ReO₃) Selenium trioxide (SeO₃) Sulfur trioxide (SO₃) Tellurium trioxide (TeO₃) Tungsten trioxide (WO₃) Uranium trioxide (UO₃) Xenon trioxide (XeO₃)
+7 oxidation state	Dichlorine heptoxide (Cl₂O₇) Manganese heptoxide (Mn₂O₇) Rhenium(VII) oxide (Re₂O₇) Technetium(VII) oxide (Tc₂O₇)
+8 oxidation state	Iridium tetroxide (IrO₄) Osmium tetroxide (OsO₄) Ruthenium tetroxide (RuO₄) Xenon tetroxide (XeO₄) Hassium tetroxide (HsO₄)
Related	Oxocarbon Suboxide Oxyanion Ozonide Peroxide Superoxide Oxypnictide
Oxides are sorted by oxidation state. Category:Oxides

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