Atomic-Scale Dynamics of the Formation and Dissolution of Carbon Clusters in SiO2

Wang, Sanwu; Ventra, Massimiliano Di; Kim, Seong‐Gon; Pantelides, Sokrates T.

doi:10.1103/physrevlett.86.5946

Cited by 95 publications

(81 citation statements)

References 17 publications

(19 reference statements)

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“…This interface cannot be wider than 15 nm, according to previous results [22]. In this near-interface reactive region [2,3,6,7,[11][12][13][14] carbon and/or excess silicon (from SiC not completely oxidized or from Si interstitials injected as a result of SiC oxidation) may also be present. The mobility of lattice oxygen could also be responsible for this phenomenon, but it has been ruled out [21] by previous analyses of samples oxidized in the 16 O 2 = 18 O 2 = 16 O 2 gas sequence.…”

Section: Volume 89 Number 25 P H Y S I C a L R E V I E W L E T T E Rmentioning

confidence: 99%

“…On the other hand, the properties of the SiO 2 =SiC interface lead to electrical characteristics worse than those of SiO 2 =Si, while the scatter of the available data [1] suggests poor interface control. Investigations of the thermal oxide film on SiC in its different regions have been pursued [2 -7], indicating that in the surface and bulk regions the oxide is similar to that grown on Si [4,8,9], that the interface is less abrupt [5,10], and that incompletely oxidized C or Si are found near the interface [2,3,6,7,[11][12][13][14]. However, a thorough understanding of the phenomena taking place during the thermal growth of SiO 2 on SiC is still missing.…”

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confidence: 99%

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Limiting Step Involved in the Thermal Growth of Silicon Oxide Films on Silicon Carbide

et al. 2002

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Thermal growth of silicon oxide films on silicon carbide in O 2 was investigated using oxygen isotopic substitution and narrow resonance nuclear reaction profiling. This investigation was carried out in parallel with the thermal growth of silicon oxide films on Si. Results demonstrate that the limiting steps of the thermal oxide growth are different in these two semiconductors, being diffusion limited in the case of Si and reaction limited in the case of SiC. This fact renders the growth kinetics of SiO 2 on SiC very sensitive to the reactivity of the interface region, whose compositional and structural changes can affect the electrical properties of the structure. DOI: 10.1103/PhysRevLett.89.256102 PACS numbers: 81.65.Mq, 61.82.Fk, 68.35.Fx, 77.55.+f In semiconductor device applications involving high power, frequency, voltage, and/or temperature, Si use is limited by its physical properties. An example is the relative narrow band gap (1.1 eV) that prevents Si devices from operating at high temperatures. The polar crystal silicon carbide (SiC) appears to be the wide band-gap material of choice since besides the wider gap (2.9 eV for the 6H polytype) SiC has other desired properties such as high thermal conductivity, breakdown voltage, and saturated electron drift velocity. It is also the only known compound semiconductor on which SiO 2 can be grown thermally. On the other hand, the properties of the SiO 2 =SiC interface lead to electrical characteristics worse than those of SiO 2 =Si, while the scatter of the available data [1] suggests poor interface control. Investigations of the thermal oxide film on SiC in its different regions have been pursued [2 -7], indicating that in the surface and bulk regions the oxide is similar to that grown on Si [4,8,9], that the interface is less abrupt [5,10], and that incompletely oxidized C or Si are found near the interface [2,3,6,7,[11][12][13][14]. However, a thorough understanding of the phenomena taking place during the thermal growth of SiO 2 on SiC is still missing.Growth of SiO 2 on SiC is much slower than on Si, presenting more scattered data [15][16][17] and differences along the polar directions [ 0001 and (0001) in the hexagonal polytypes]. Several authors have tried to model the kinetics of the thermal growth of SiO 2 on SiC [15,17,18], mostly within the framework of the Deal and Grove model [19], which satisfactorily describes the thermal growth of SiO 2 on Si in dry O 2 for oxide thicknesses above 20 -30 nm. This model is based on a stationary flux of O 2 , the only mobile species, across the growing oxide and on reaction with Si to form SiO 2 only at an abrupt interface. These efforts were curve fittings which did not consider the reaction mechanisms and limiting steps characteristic of the SiO 2 =SiC system. The elucidation of the oxidation mechanismsidentification of the limiting steps and the mobile species and how they are transported during oxide thermal growth-is necessary to develop an oxidation model for SiC allowing prediction and control of the ...

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Section: Volume 89 Number 25 P H Y S I C a L R E V I E W L E T T E Rmentioning

confidence: 99%

mentioning

confidence: 99%

Limiting Step Involved in the Thermal Growth of Silicon Oxide Films on Silicon Carbide

et al. 2002

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“…19,20,21,22,23,24 The results reported in this paper were obtained using the Vienna ab-initio simulation package (VASP). 20,21,22 The exchange-correlation effects were treated with the generalized gradient-corrected exchange-correlation functionals (GGA) given by Perdew and Wang.…”

Section: Methodsmentioning

confidence: 99%

First-principles calculations for the adsorption of water molecules on theCu(100)surface

2004

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First-principles density-functional theory and supercell models are employed to calculate the adsorption of water molecules on the Cu(100) surface. In agreement with the experimental observations, the calculations show that a H2O molecule prefers to bond at a one-fold on-top (T1) surface site with a tilted geometry. At low temperatures, rotational diffusion of the molecular axis of the water molecules around the surface normal is predicted to occur at much higher rates than lateral diffusion of the molecules. In addition, the calculated binding energy of an adsorbed water molecule on the surfaces is significantly smaller than the water sublimation energy, indicating a tendency for the formation of water clusters on the Cu(100) surface.

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“…In many application areas, for instance those related to aerospace, automotive and petroleum industries, there is a need for electronic devices that can operate at high power levels, high temperatures, high frequencies and in harsh environments. Silicon (Si) cannot meet these requirements; SiC can [2][3][4]. In addition, because of its exemplary chemical and mechanical properties SiC, in combination with Si, is finding wider application in sensors and micro-electromechanical systems (MEMS) [5][6][7][8][9].…”

Section: Introductionmentioning

confidence: 99%

Anodic etching of SiC in alkaline solutions

Dorp

Weyher

Kelly

2007

J. Micromech. Microeng.

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The photoelectrochemistry of silicon carbide in alkaline solution was investigated with a view to wet-chemical etching applications. Anodic dissolution and passivation of the p-type semiconductor was observed in the dark; illumination with supra-bandgap light was required for oxidation of the n-type electrode. At low KOH concentrations and low light intensities, diffusion-controlled etching is observed for n-type SiC. We show that open-circuit photoetching can be used for defect revealing. Furthermore, based on the electrochemical properties of silicon carbide and silicon, we expect various material-selective etching processes to be possible.

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Atomic-Scale Dynamics of the Formation and Dissolution of Carbon Clusters in SiO2

Cited by 95 publications

References 17 publications

Limiting Step Involved in the Thermal Growth of Silicon Oxide Films on Silicon Carbide

Limiting Step Involved in the Thermal Growth of Silicon Oxide Films on Silicon Carbide

First-principles calculations for the adsorption of water molecules on theCu(100)surface

Anodic etching of SiC in alkaline solutions

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