Fact-checked by Grok 2 weeks ago

Silicon monoxide

Silicon monoxide, with the chemical formula SiO, is an inorganic compound in which silicon adopts the uncommon +2 oxidation state, forming a diatomic molecule in the vapor phase but typically existing as an amorphous solid that undergoes nanoscale disproportionation into silicon-rich and silica-like (SiO₂) regions. The solid form appears as a black-brown to loess-colored amorphous powder with a density of approximately 2.15 g/cm³, high melting and boiling points, and insolubility in water, though it dissolves in hydrofluoric acid, or mixtures thereof with nitric acid, to release silicon tetrafluoride. Chemically stable at room temperature and generally unreactive with water, dilute acids, or alkalis under ambient conditions, though it reacts with hydrofluoric acid and hot concentrated alkali hydroxides,[] SiO oxidizes to white silica (SiO₂) upon heating in air and can disproportionate further into elemental silicon and SiO₂ above 600°C in inert atmospheres. In its amorphous state, SiO features a heterogeneous structure with suboxide tetrahedra at interfaces between amorphous Si clusters and an SiO₂ matrix, as revealed by advanced techniques like angstrom-beam and high-energy ; this resolves long-standing debates on its composition and distinguishes it from pure Si or SiO₂. Theoretical studies indicate that while crystalline ground-state structures exist with Si–Si bonds and Si–O–Si bridges, making it semiconducting at 1 atm, the material's practical forms are predominantly amorphous without large-scale segregation, and (2SiO → Si + SiO₂) is exothermic, limiting thermodynamic stability. A two-dimensional variant, orthorhombic SiO (Orth-SiO), has been predicted to be stable with a direct of 1.52 eV, high hole mobility (up to 8.5 × 10³ cm²·V⁻¹·s⁻¹), and potential for optical and electronic applications, though it remains largely theoretical. SiO is prepared industrially by high-temperature reduction of SiO₂ with or carbon under , followed by rapid , yielding material volatile above 1100°C suitable for into thin . These exhibit strong UV absorption extending into the visible, a ranging from ~1.4 (oxidized) to ~2, high , good adhesion to substrates like , and to and hygroscopicity, though they oxidize slowly in air. Notable applications include optical coatings, insulating layers in , capacitor dielectrics, protective overcoats for mirrors, anode materials in lithium-ion batteries, and precursors for high-purity silica or in ceramics and semiconductors.

Physical and chemical properties

General characteristics

Silicon monoxide is an with the SiO, in which silicon exhibits a +2 . Its is 44.08 g/. In its solid form, silicon monoxide appears as a brown-black or yellowish-brown glassy solid with a of 2.13 g/cm³. It is insoluble in . In the gas phase, SiO exists as a featuring a Si–O ranging from 148.9 to 151 pm. Silicon monoxide is sensitive to air and moisture, readily undergoing surface oxidation to form a protective layer of .

Thermal and optical properties

Silicon monoxide (SiO) in its solid polymeric form exhibits notable thermal characteristics. The material sublimes appreciably at temperatures above 1,000 °C and becomes volatile above 1,100 °C, facilitating its use in processes. Thermal stability is maintained up to approximately 800 °C, beyond which into silicon and begins around 850 °C and proceeds significantly up to 1,050 °C. Vapor pressure variations with temperature are critical for evaporation applications, where SiO's equilibrium vapor pressure over a mixture of silicon and silica follows the logarithmic relation: \log_{10} \left( \frac{p}{\mathrm{Pa}} \right) = 13.613 - \frac{1.785 \times 10^4}{T} with T in kelvin; this equation describes pressures in the range relevant to high-temperature evaporation rates. The evaporation coefficient is approximately 0.007 over such mixtures, indicating moderately efficient sublimation under vacuum. These properties underscore SiO's heat resistance, enabling its application in thermally demanding environments like protective coatings that withstand elevated temperatures without rapid degradation. Optically, evaporated thin films of SiO display strong in the ultraviolet region (below 0.4 μm), which tails into the , rendering the material opaque or brownish in thicker deposits. In the , laboratory measurements reveal a prominent maximum at around 10 μm, attributed to Si-O vibrational modes, with in broader mid- to far-IR ranges outside this band. The of SiO films is approximately 1.97 at visible wavelengths (e.g., 0.6 μm), decreasing slightly toward the IR, which supports its utility in optical multilayer designs. As an , solid SiO possesses a dielectric constant of about 6 for pure forms, with high that resists breakdown under electric fields, making it suitable for capacitive and insulating layers in thin-film devices. This value positions SiO between elemental (dielectric constant ~11.7) and (~3.9), reflecting its intermediate oxidation state and amorphous structure.

Reactivity and stability

Silicon monoxide (SiO) exhibits distinct reactivity depending on its form and environmental conditions, primarily driven by its +2 , which renders it prone to further oxidation. In the gaseous molecular form, SiO reacts with oxygen to form (SiO₂), as described by the reaction 2SiO + O₂ → 2SiO₂, though this process is endothermic with high activation barriers, making it kinetically slow at (upper limit rate constant of 4.5 × 10⁻¹⁵ cm³ s⁻¹ at 293 K). Upon exposure to air, solid SiO undergoes gradual oxidation, forming a protective passivation layer of SiO₂ that limits further degradation, similar to the native on surfaces. This passivation enhances the durability of SiO films, which remain abrasion-resistant and non-hygroscopic under ambient conditions below 200°C. In the gas phase, SiO interacts with H₂O to form stable intermediates like Si(OH)₂ rather than directly decomposing to SiO₂ and H₂, as the latter pathway is endothermic (ΔH = 56.6 kJ/mol) and features high activation energies, rendering it inefficient at typical temperatures. SiO films deposited under certain conditions (e.g., grazing incidence angles) show increased instability in atmospheres, buckling due to hydrolytic stress. Stability of SiO varies markedly between inert and oxidizing environments. In inert atmospheres such as vacuum or dry , solid SiO maintains at temperatures up to 200°C, with films exhibiting long-term durability after (e.g., 250°C annealing). Conversely, in oxidizing environments, reactivity accelerates, with SiO burning in pure oxygen to yield SiO₂, driven by the thermodynamic favorability at elevated temperatures (e.g., above 1000 K in combustion-like conditions). The gaseous form is particularly reactive in such settings, facilitating rapid oxidation pathways involving radicals like , which are exothermic and barrier-free (ΔH ≈ -5.0 kJ/mol for SiO + → H + SiO₂). Differences in reactivity between the gaseous and solid forms stem from their structural disparities. Gaseous SiO exists as a with high volatility above 1100°C, enabling efficient participation in gas-phase oxidation and reactions in astrophysical or high-temperature settings. In contrast, the solid polymeric form is an amorphous network, often viewed as a disproportionated of Si and SiO₂, which reduces its reactivity due to polymerization and the encapsulating SiO₂ layer, making it more stable against immediate decomposition in ambient conditions. This polymeric structure confers lower sensitivity to environmental interactions compared to the monomeric gas, though prolonged exposure still promotes slow oxidation.

Structural forms

Gaseous molecular form

Silicon monoxide in its gaseous molecular form exists as the diatomic species SiO, characterized by a strong Si–O bond with significant triple bond character due to the involvement of pπ–pπ multiple bonding interactions, analogous to but with reduced π-backbonding from silicon's larger atomic size. The D_0 for SiO(g) → Si(g) + O(g) is approximately 800 kJ/mol. The vibrational frequency of the ground electronic state, derived from and , is \omega_e \approx 1245 cm^{-1}, reflecting the stiff nature of the bond. Spectroscopic investigations reveal that the SiO molecule exhibits a permanent of 3.10 in its vibrational (v=0), enabling detection via rotational and vibrational transitions in the , , and regions. These transitions, particularly the fundamental vibrational band near 8 μm and pure rotational lines in the J=1–0 transition at approximately 43 GHz for ^{28}Si^{16}O, are crucial for identifying the in laboratory and astrophysical contexts. The diatomic SiO monomer is stable only at elevated temperatures above 1000°C, where it predominates in the vapor phase over polymeric forms; below this threshold, it tends to disproportionate according to the equilibrium $2SiO(g) ⇌ Si(s) + SiO_2(s), with the forward reaction favored at higher temperatures due to entropy gains from gas production. This transient nature limits its persistence under ambient conditions, as the equilibrium constant K_p increases with temperature, reaching values that support significant SiO partial pressures around 1200–1500 K. In laboratory settings, gaseous SiO is generated as a transient through of solid SiO or mixtures of and silica at temperatures exceeding 1000°C, producing monomeric vapor via the reaction Si(s) + SiO_2(s) → 2SiO(g). Alternatively, of targets in controlled oxygen atmospheres yields SiO monomers, allowing spectroscopic interrogation in expansion-cooled molecular beams. These methods ensure isolation of the diatomic form for studies of its electronic (X^1\Sigma^+) and excited states.

Solid polymeric form

The solid polymeric form of silicon monoxide, denoted as (SiO)_n, adopts an amorphous structure featuring interconnected Si-O-Si chains and Si-Si bonds, with silicon maintaining an average of +2. This network forms a glass-like morphology, often manifesting as nanoscale clusters embedded within an SiO₂-like matrix, connected by suboxide tetrahedra at the interfaces. Upon condensation from the vapor phase, typically via or , the material solidifies into a brown-black, brittle solid with a of approximately 2.15 g/cm³. Deviations from ideal 1:1 are common, resulting in Si-rich regions that arise from partial during formation, enhancing its heterogeneous character. Electrically, amorphous SiO functions as a wide-bandgap or , with an optical bandgap of about 4 eV for compositions near x=1 in SiO_x, though defect-induced states can enable hopping conduction in Si-rich variants. Paramagnetism originates from unpaired spins at structural defects, such as silicon dangling bonds, as observed via in evaporated films. In contrast to SiO₂, which exhibits a higher (~2.2 g/cm³), a larger bandgap (~9 ), and greater chemical inertness, the suboxide nature of SiO imparts enhanced reactivity, including facile oxidation to SiO₂ and decomposition into elemental and silica at elevated temperatures.

Synthesis and production

Historical methods

Silicon monoxide (SiO) was first synthesized and reported in 1887 by chemist Charles F. Mabery, who obtained it as a greenish-yellow, vitreous, amorphous substance through the partial reduction of silica-containing ores, such as or clay, with in an electric like the Cowles process. Mabery's analysis confirmed the composition, with samples yielding 96.45% to 99.88% SiO upon conversion to , and a specific gravity of 2.893. An improved synthesis method was developed in 1905 by Henry Noel Potter, an engineer at , who heated a mixture of granular and silica in a electric to approximately 1,700 °C, producing SiO vapor that condensed into a solid upon cooling. Potter's approach used a slight excess of to minimize residual silica in the product and avoided the formation of or by maintaining low pressure, marking a significant advancement in isolating purer SiO. By the early , SiO was recognized as a silicon suboxide, with the key reaction understood as the : \text{SiO}_2 + \text{Si} \rightleftharpoons 2\text{SiO (g)} This gaseous intermediate forms at high temperatures and condenses to the solid form, as detailed in Potter's work and subsequent studies. Isolation of stable SiO proved challenging due to its tendency to disproportionate into and , even at moderate temperatures, complicating efforts to obtain pure samples without rapid or conditions.

Modern laboratory and industrial production

In modern laboratory settings, silicon monoxide (SiO) is commonly produced in gaseous form through vacuum thermal evaporation of a mixture of silicon (Si) and silicon dioxide (SiO₂). The mixture is heated to temperatures between 1,800°C and 2,000°C under high vacuum conditions, facilitating the reaction Si + SiO₂ → 2SiO, which generates SiO vapor for subsequent deposition as amorphous thin films. This method allows for controlled deposition rates and is widely used for optical and protective coatings due to the material's volatility above 1,100°C. Chemical vapor deposition (CVD) variants, including plasma-assisted techniques, enable the synthesis of SiO thin films with enhanced uniformity and adhesion. In (PECVD), precursors such as (SiH₄) or tetraethoxysilane () are activated in a low-pressure plasma environment to deposit SiO-rich films at substrate temperatures below 400°C, offering scalability for applications. Recent advancements post-2000 incorporate for gas-phase SiO studies, where pulsed lasers (e.g., 266 nm Nd:YAG) ablate targets in oxygen-containing atmospheres to generate SiO molecules for spectroscopic analysis. On an industrial scale, SiO is generated as a during the carbothermic reduction of SiO₂ for silicon metal production, following the reaction SiO₂ + 2C → Si + 2CO, where intermediate SiO forms at temperatures exceeding 1,800°C in submerged arc furnaces. The gaseous SiO can be captured and purified through to separate it from contaminants like and unreacted silica, yielding material suitable for further processing. Laboratory production of SiO achieves yields up to 99% purity through optimized and , though challenges persist with contamination from residual oxygen or carbon impurities, necessitating inert atmospheres and high-vacuum systems. A 2022 study demonstrated gas-phase SiO formation via non-adiabatic reactions between atomic and molecular oxygen in single-collision events, providing insights for astrophysical simulations while highlighting potential for high-purity, controlled .

Applications

Thin film deposition and coatings

Silicon monoxide (SiO) is commonly employed in deposition through thermal evaporation in systems, where solid SiO is heated to temperatures between 1,000 and 1,250 °C to produce vapors that condense as amorphous on substrates such as optical lenses and mirrors. This method, established since the in the industry, allows for precise control of thickness using rate monitoring to achieve uniform layers typically ranging from tens to hundreds of nanometers. During deposition, exposure to residual oxygen often results in , forming SiO_x with compositions intermediate between SiO and SiO_2, which enhances adhesion and stability. The deposited films exhibit a typically in the range of 1.45 to 1.7 in the , depending on deposition conditions like substrate temperature and oxygen , making them suitable for anti-reflective applications by minimizing light reflection at interfaces. These amorphous layers demonstrate low absorption in the near-infrared region, enabling their use in optical components requiring high transmission beyond 1 μm, while compatibility with environments facilitates integration into multi-layer stacks. In electronics, evaporated SiO films serve as passivation layers on semiconductors, such as in high-electron-mobility transistors (HEMTs), where they reduce surface leakage currents and improve breakdown voltage by mitigating trap states. Historically, since the mid-1950s, SiO-based coatings have been widely adopted in the sector for anti-reflective treatments on precision lenses and mirrors, enhancing light transmission in cameras and telescopes. SiO antireflection coatings have also been applied to InP/ solar cells to increase short-circuit currents.

Metallurgical and ceramic uses

In metallurgical processes, gaseous (SiO) serves as a key intermediate for transfer during ironmaking in blast furnaces. Formed by the reduction of in ash or at high temperatures, SiO gas reacts with carbon-saturated iron to dissolve into the hot metal, contributing to the desired content in . This mechanism is critical for controlling levels, which influence the mechanical properties of subsequent products. In production via carbothermic reduction, SiO emerges as a volatile from the of silica (SiO₂) with carbon, potentially leading to losses of 10-20% if not recovered. efforts capture and reintroduce SiO into the process to improve and reduce material waste, often through and reintegration in the . Additionally, SiO facilitates vapor-phase transport in certain techniques, aiding the deposition of layers or related compounds during high-temperature synthesis. SiO is used as a precursor in the production of ceramics, including high-purity silica and . Industrial production of SiO for metallurgical and applications occurs on a significant scale, with global market values exceeding USD 160 million annually as of , reflecting thousands of tons utilized in these sectors. However, the carbothermic synthesis process generates substantial emissions, prompting ongoing efforts to mitigate environmental impacts through process optimizations and alternative reduction methods. SiO has also found application as an anode material in lithium-ion batteries, where its nanostructured form accommodates volume expansion during cycling, improving battery performance and capacity.

Astrophysical occurrence

Detection in interstellar medium

Silicon monoxide (SiO) was first detected in the in 1971 through observations of its rotational J=3–2 transition near 130.2 GHz toward the dense Sagittarius B2 (Sgr B2) using the 11 m telescope at . This millimeter-wave revealed emission at a radial velocity consistent with other molecules in the region, confirming SiO as a gaseous in the interstellar environment with an estimated column of approximately 4 × 10^{13} cm^{-2}. Subsequent surveys have identified SiO abundances in circumstellar envelopes surrounding late-type stars, where it often manifests as emission in vibrational states (v=1 or v=2) and rotational transitions such as J=1–0 at 43.4 GHz or J=2–1 at 86.8 GHz, particularly in bipolar outflows from evolved stars like . SiO is also prevalent in supernova remnants, such as , where it traces molecular gas through thermal emission in the ground vibrational state. These detections highlight SiO's role as a shock tracer, with enhanced abundances (up to 10^{-7} relative to H_2) in regions of high-velocity gas interactions. Recent observations using the Atacama Large Millimeter/submillimeter Array () have mapped SiO emission in shocked regions of massive star-forming clouds and protostellar outflows, revealing detailed spatial distributions with resolutions down to ~0.1 pc. These studies, spanning 2015 to 2025, report column densities ranging from ~10^{12} to 10^{16} cm^{-2} in environments like infrared dark clouds and high-mass protostellar objects, often associated with broad-line profiles indicative of velocities exceeding 20 km s^{-1}. Isotopic variants, including ^{29}SiO and ^{30}SiO, have been observed in dense molecular clouds such as and Sgr B2, enabling determinations of silicon isotopic ratios (e.g., ^{28}Si/^{29}Si ≈ 19–20 and ^{28}Si/^{30}Si ≈ 90–100) that reflect Galactic chemical evolution. In these clouds, SiO abundances correlate with those of H_2O, both elevated in shocked layers where sputtering releases silicon and oxygen from dust grains.

Role in cosmic chemistry

Silicon monoxide (SiO) serves as a critical precursor in the formation of within cosmic environments, particularly through gas-phase oxidation s that facilitate the growth of nanoparticles. In these processes, SiO reacts with hydroxyl radicals (), such as in the pathway SiO + + SiO₂, which is nearly thermoneutral with a low barrier, efficient oxidation even at low temperatures typical of regions. This proceeds via an and supports the of silica (SiO₂) and higher-order s, ultimately contributing to the aggregation of grains essential for . Recent studies highlight non-adiabatic pathways for SiO formation itself, where ground-state atomic (Si) collides with molecular oxygen (O₂) in a barrierless, exoergic involving intersystem crossings, producing highly rovibrationally excited SiO without forming SiO₂. This underscores SiO's role as a fundamental building block for nanoparticles in cold molecular clouds. In astrophysical shocks, SiO is released into the gas phase via of grains, where high-velocity impacts by neutral particles erode grain cores, injecting SiO and tracing regions of turbulent, high-velocity gas flows. This dominates in C-type shocks driven by , with SiO abundances enhanced by factors of up to 10⁶ relative to quiescent values. Such releases are particularly evident in protostellar jets, where SiO abundance spikes—reaching at least 10% of total elemental in dusty jets like HH212—signal recent grain disruption and provide kinematic probes of outflow dynamics. Within dark clouds, SiO contributes to silicon chemistry primarily through neutral-neutral reactions, which dominate over ion-molecule pathways due to the prevalence of silicon in excited states at temperatures above 30 K. Key reactions include + → SiO + H and + O₂ → SiO + O, with the latter favored by the higher abundance of O₂, enabling SiO production under dense conditions (n(H₂) ≥ 10⁶ cm⁻³). These processes link SiO to broader networks influencing by facilitating dust grain growth and H₂ formation on surfaces, while also informing the chemical heritage of solar system materials through presolar inclusions. Post-2019 laboratory simulations have advanced understanding of SiO's role in dust formation by modeling the clustering of SiO with SiO₂ to form proto-silicate via , revealing aggregation pathways that mimic at low temperatures. These studies demonstrate bottom-up assembly of SiO aggregates into larger silicates, supporting efficient production in circumstellar outflows. Furthermore, SiO detections in atmospheres, such as the ultrahot WASP-121b where Si/H ratios exceed stellar values by over 2.5 times, imply ongoing rocky accretion and thermal inversions driven by SiO opacity, with implications for volatile enrichment beyond H₂O ice lines (as of June 2025).

References

  1. [1]
    Atomic-scale disproportionation in amorphous silicon monoxide
    May 13, 2016 · It has been deduced that amorphous silicon monoxide undergoes an unusual disproportionation by forming silicon- and silicon-dioxide-like regions.
  2. [2]
    Silicon Monoxide at 1 atm and Elevated Pressures: Crystalline or Amorphous?
    ### Summary of Silicon Monoxide Structures
  3. [3]
    [PDF] Properties, Oxidation, Decomposition, and Applications of Thin Films ...
    A material sattisfylng the chemical formula for silicon mon- oxide can be made by controlled condensation of vapors obtained by.<|control11|><|separator|>
  4. [4]
    Silicon monoxide properties and preparation - Infomak
    Jul 6, 2022 · The molecular structure of silicon monoxide is formed by covalent bonding between a silicon atom and an oxygen atom. The silicon atom in this ...
  5. [5]
    [PDF] Ground state structure and physical properties of silicon monoxide ...
    May 25, 2020 · The ground state structure of 2D SiO, Orth-SiO, is thermally, dynamically, and mechanically stable with a 1.52 eV band gap. It has lattice ...
  6. [6]
    Silicon Monoxide - Properties and Evaporation Techniques
    Silicon monoxide (SiO) is volatile above 1100°C, forming amorphous films with high dielectric strength, good adhesion to glass, and is not hygroscopic. It is ...Missing: structure | Show results with:structure
  7. [7]
    Silicon Monoxide | AMERICAN ELEMENTS ®
    Silicon Monoxide is a highly insoluble thermally stable Silicon source suitable for glass, optic Ultra High Purity(99.999%) Silicon Oxide Pieces ...
  8. [8]
    Silicon oxide (SiO) | OSi | CID 66241 - PubChem - NIH
    Silicon oxide (SiO) | OSi | CID 66241 - structure, chemical names, physical and chemical properties, classification, patents, literature, biological ...Missing: applications | Show results with:applications
  9. [9]
    Silicon(II) oxide (SiO)-Powder - FUNCMATER
    Rating 5.0 (84) Silicon monoxide is unstable and oxidizes into silica in the air. Chemical formula:SiO. Molar mass:44.08 g/mol. Appearance:brown-black glassy solid. Density: ...
  10. [10]
    silicon monoxide - the NIST WebBook
    Formula: OSi · Molecular weight: 44.0849 · IUPAC Standard InChI: InChI=1S/OSi/c1-2. Copy. InChI version 1.06 · IUPAC Standard InChIKey: LIVNPJMFVYWSIS-UHFFFAOYSA-N
  11. [11]
    SiO properties
    Its molecular structure exhibits a bond length of 148.9-151.0 pm with significant triple bond character despite electronic configuration challenges. The ...
  12. [12]
    [PDF] AGR1277 - Silicon Monoxide (SiO) Chips - Safety data sheet
    Feb 27, 2019 · Evaporation rate. Not applicable. · Solubility in / Miscibility with water: Insoluble. · Partition coefficient: n-octanol/water:.
  13. [13]
    [PDF] Silicon Monoxide - Properties and Evaporation Techniques
    Silicon monoxide, SiO, is volatile at temperatures above 1100°C and can be readily vacuum deposited to form amorphous films with small grain size, high ...
  14. [14]
    Photoluminescence from silicon nanoparticles prepared from bulk ...
    Sep 16, 2005 · These measurements indicate that the disproportionation reaction starts at approximately 850 ° C and continues up to 1050 ° C ⁠. Grains of SiO ...
  15. [15]
    Silicon monoxide pressures due to the reaction between solid ...
    The silicon monoxide pressures may be represented by the equation: log10(p/Pa)=13.613 − 1.785 x 104(T/K)−1.
  16. [16]
    Optical Properties of Silicon Monoxide in the Wavelength Region ...
    Silicon monoxide films exhibit strong absorption in the ultraviolet which extends into the visible, and an infrared absorption maximum at 10 microns which ...Missing: review | Show results with:review<|control11|><|separator|>
  17. [17]
    Infrared optical properties of silicon monoxide films
    We estimate that the inaccuracy in the data for ε1 and ε2 is about 5% for λ > 12 μm, while it is substantially larger around the absorption peak at λ ∼ 10 μm.
  18. [18]
    Refractive index of SiO (Silicon monoxide) - Hass
    The refractive index of SiO is 1.9690, with an extinction coefficient of 0.0010000, according to Hass and Salzberg 1954.
  19. [19]
    [PDF] Compilation of the Static Dielectric Constant of Inorganic Solids
    Oct 29, 2009 · Silicon monoxide. 5.8. r.t.. 10. 3. 58. ~ m. Si0. 2. Silicon dioxide. 8. 11. =4.42. 10. 9.4xlO. 47. 103,106. 8. 22. =4.41. 9.4xl0. 1O. 47. £.33= ...
  20. [20]
    Mechanisms and Thermochemistry of Reactions of SiO and Si 2 O 2 ...
    May 2, 2023 · This paper reports on computational studies of gas-phase reactions of SiO and Si 2 O 2. The oxidation of SiO can initiate efficient formation of silica or ...Benchmark Energetics · Reactions Of Oh With Sio And... · Reactions Of Ho With Sio And...
  21. [21]
    Stress Anisotropy in Silicon Oxide Films
    However, films formed by depositing at grazing incident angles (>30°) are very unstable and invariably buckle and rupture when exposed to atmospheres of water ...
  22. [22]
    Dissociation Energy and Ionization Potential of Silicon Monoxide
    The dissociation energy of SiO(g) has been determined mass spectrometrically by studying the isomolecular equilibrium Ge(g) + SiO(g) = GeO(g) + Si(g).
  23. [23]
    Experimental data for SiO (Silicon monoxide) - CCCBDB
    ... Diatomic ... 0.0000, 1.5097. Atom - Atom Distances bond lengths. Distances in Å. Si1, O2. Si1, 1.5097. O2, 1.5097. Calculated geometries for SiO (Silicon monoxide) ...
  24. [24]
    Electric Dipole Moment of SiO and GeO - AIP Publishing
    Apr 1, 1970 · The molecular beam electric resonance spectra of SiO and GeO have been measured. The electric dipole moments (in Debye) of SiO and GeO in the
  25. [25]
    ExoMol line lists – II. The ro-vibrational spectrum of SiO
    Accurate rotational–vibrational line lists are calculated for silicon monoxide. Line lists are presented for the main isotopologue, 28Si16O, and for four ...
  26. [26]
    (PDF) SiO vapor pressure in an SiO2 glass/Si melt/SiO gas ...
    Aug 6, 2025 · SiO vapor pressure concerning Czochralski (CZ) Si crystal growth has been measured successfully by an SiO2 glass/Si melt/SiO gas equilibrium system.
  27. [27]
    Structure, vibrations and electronic transport in silicon suboxides
    This work focuses on the structure and electronic transport in atomistic models of silicon suboxides (a-SiOx; x = 1.3,1.5 and 1.7) used in the fabrication ...
  28. [28]
    Electronic state characterization of SiOx thin films prepared by ...
    SiOx thin films with different stoichiometries from SiO1.3 to SiO1.8 have been prepared by evaporation of silicon monoxide in vacuum or under well-controlled
  29. [29]
    An EPR investigation of SiOx films with columnar structure
    Aug 5, 2025 · The thin (about 950 nm) SiO x film was deposited by thermal evaporation of silicon monoxide SiO (Cerac Inc.) in vacuum (1-2) ×10 − 3 Pa on ...
  30. [30]
    [PDF] American chemical journal - University of Illinois Library
    On Certain Substituted Acrylic and Propionic Acids. By. Charles F. Maybery, i. On the Composition of Certain Products from the Cowi.es. Electrical Furnace. By ...
  31. [31]
    US875675A - Method of producing silicon monoxid. - Google Patents
    METHOD OF PRODUCING SIL ICON MONOXID. Specification of Letters Patent. Patented Dec. 31, 1907. Application filed June 10. 1905. Serial K0464553- of New ...
  32. [32]
    [PDF] Preparation of Silicon Monoxide by Using Electric Current Assisted ...
    Jan 29, 2024 · SiO was first reported by Mabery in 1886 [10]. When reducing silicon dioxide with charcoal in an electric furnace, a glassy, amorphous green ...Missing: Maybery | Show results with:Maybery
  33. [33]
    Deposition of silicon oxide films from TEOS by low frequency plasma ...
    Mar 1, 1993 · In this work, the authors deposited silicon oxide films using TEOS as a silicon source by using a low frequency (50 Hz) plasma CVD. It has been ...Missing: monoxide | Show results with:monoxide
  34. [34]
    [PDF] Gas-Phase Formation of Silicon Monoxide via Non-Adiabatic ...
    Jul 8, 2022 · To limit the degrees of freedom of the geometry scan, the Si-O bond length is fixed to be 152 pm. (identical to the Si-O bond length of i5). The ...Missing: diatomic | Show results with:diatomic
  35. [35]
    Silicon carbide formation from methane and silicon monoxide - Nature
    Dec 11, 2020 · It was confirmed that SiC may form from SiO and methane. Increasing the methane content to 5% caused a significant increase in SiC formation.
  36. [36]
    Production of Si by vacuum carbothermal reduction of SiO2 using ...
    Sep 10, 2010 · The carbothermal reduction of silica to silicon was examined thermodynamically and demonstrated experimentally at vacuum pressures.Missing: byproduct purification
  37. [37]
    High-Purity Silicon Monoxide (SiO): Properties, Applications, and ...
    Oct 15, 2025 · Our silicon monoxide boasts a purity of at least 99.00%, crucial for demanding applications like semiconductor fabrication and optical coating, ...
  38. [38]
    Gas-phase formation of silicon monoxide via non-adiabatic reaction ...
    Aug 8, 2022 · Silicon monoxide can be formed via a barrierless, exoergic, single-collision event between ground state molecular oxygen and atomic silicon involving non- ...
  39. [39]
    Optical constants of evaporation-deposited silicon monoxide films in ...
    Jun 2, 2009 · The transmittance of silicon monoxide films prepared by thermal evaporation was measured from 7.1 to 800 eV and used to determine the ...
  40. [40]
    Disproportionation and Vaporization of Solid Silicon Monoxide - 1967
    The vaporization rate of solid SiO was studied in the temperature range 1005° to 1475°C. It was concluded that (a) in an argon atmosphere the vaporization ...
  41. [41]
    Refractive index of vacuum-evaporated SiO thin films
    Our results demonstrate the possibility of obtaining SiO thin films with different and controlled refractive indices by controlling the substrate temperature.
  42. [42]
    Silicon monoxide antireflection coatings for InP/CdS solar cells
    Jan 1, 1978 · A hard and durable antireflection coating that bonds well to cadmium sulfide has been developed. Silicon monoxide films evaporated at 140°C ...Missing: deposition | Show results with:deposition
  43. [43]
    Kinetics of the reaction of SiO(g) with carbon saturated iron
    The reaction of SiO(g) with carbon saturated iron plays an important role in silicon transfer in the iron blast furnace. In the tuyere zone SiO(g) is ...
  44. [44]
    Chemistry of the Ironmaking by Blast Furnace Process - IspatGuru
    Following these reactions, silicon is transferred to iron droplets by reaction with SiO in the gas phase [SiO (gas) + C = Si + CO]. As iron droplets containing ...
  45. [45]
    Method for producing silicon by carbothermic reduction of silicon ...
    The submerged arc furnace is the main industrial process currently utilized to produce silicon by carbothermal reduction of silicon dioxide and carbonaceous ...
  46. [46]
    A Comprehensive Guide to Silicon Monoxide (SiO) and Its ...
    Oct 23, 2024 · Its unique properties—such as heat resistance, mechanical strength, and infrared blocking—make it useful in industries from electronics to ...
  47. [47]
    Silicon Monoxide Market Trends, Growth, & Share-2033
    The global silicon monoxide market size was valued at USD 167.58 million in 2024 and is projected to reach a value from USD 186.35 million in 2025 to USD 435.67 ...Missing: refractories | Show results with:refractories
  48. [48]
    Stellar masers, circumstellar envelopes, and supernova remnants
    May 15, 2007 · Abstract: This paper reviews recent advances in the study or circumstellar masers and masers found toward supernova remnants.Missing: SiO abundance stars emissions
  49. [49]
    Probing Molecules in Supernova Remnants — NRAO Science Site
    ALMA detected cold (20–170 K) CO, 28SiO, HCO+ and SO, with weaker lines of 29SiO from ejecta, the first identification of HCO+and SO in a young supernova ...
  50. [50]
    A survey of SiO J = 1−0 emission toward massive star-forming regions
    2.2 SiO (1–0) observations and data reduction. Observations of the rotational ground state transition of SiO (v = 0, J = 1–0, 43.42376 GHz) toward 366 ...
  51. [51]
    The Diffuse Interstellar Medium with Exceptionally High SiO ...
    Jun 9, 2023 · We detect SiO in five of eight directions probing diffuse and translucent environments without ongoing star formation. Our results demonstrate ...
  52. [52]
    The relative abundances of Si-28, Si-29, and Si-30 in the interstellar ...
    ... 29SiO and 30SiO have been made toward four dense molecular clouds. ... The results are utilized to derive relative isotopic abundances in the interstellar medium.Missing: detection | Show results with:detection
  53. [53]
    Observations of phosphorus-bearing molecules in the interstellar ...
    Simultaneous SiO observations confirm that also in these extragalactic clouds the abundances of PN and SiO are correlated, poiting to a shocked origin of PN as ...
  54. [54]
    SiO production in interstellar shocks.
    **Summary of SiO Production via Sputtering in Interstellar Shocks:**
  55. [55]
    High SiO abundance in the HH212 protostellar jet
    Gas-phase SiO at high velocity contains at least 10% of the elemental silicon if the jet is dusty, and at least 40% if the jet is dust-free.
  56. [56]
    [PDF] Silicon Chemistry in Interstellar Clouds
    Because the dipole moment of Si0 (3.1 Debye) is much larger than that of CO, the Si0 emission arises from dense regions, typically with n(H2) 2 lo4 - lo6 m ...
  57. [57]
    Formation of Interstellar Silicate Dust via Nanocluster Aggregation
    The present work deals with modeling this proto-silicate nanocluster aggregation process by means of quantum chemical density functional theory calculations.
  58. [58]
    Photochemical properties of a potential interstellar dust precursor
    Jun 19, 2023 · Several laboratory experiments showed that SiO can form larger aggregates even at low temperature, suggesting that bottom-up aggregation can ...
  59. [59]
    SiO and a super-stellar C/O ratio in the atmosphere of the ... - Nature
    Jun 2, 2025 · Refractory elements such as iron, magnesium and silicon can be detected in the atmospheres of ultrahot giant planets.