Chemical Vapor Deposition of Amorphous Silicon Using Tetrasilane

Kanoh, Hiroshi; Sugiura, Osamu; Matsumura, Masakiyo

doi:10.1143/jjap.32.2613

Cited by 25 publications

(17 citation statements)

References 24 publications

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“…The experimental rate of particle growth d(r)/dt (where r is the particle radius) obtained from Figure 5 for (when disilane and t ϭ 0.1 s trisilane have the concentrations close to maximal) was compared with W evaluated from (3). We also took into account that under deposition from trisilane the rate of silicon layer growth is approximately two times higher than under deposition from disilane [46,53]. For the estimation showed that neous decomposition of silane and disilane are also the same and equals to Ͻ 0.5%.…”

Section: On Heterogeneous Decomposition Of Silane Disilane and Trismentioning

confidence: 99%

Studying of silane thermal decomposition mechanism

Onischuk

Strunin

Ushakova

et al. 1998

Int. J. Chem. Kinet.

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The mechanism of silane thermal decomposition is investigated in a flow reactor. The time dependencies of silane consumption and disilane formation were compared with those parameters of solid product (aerosol particles) such as concentration, total hydrogen content in solid product, and fraction of hydrogen contained in solid product as polyhydride groups (SiH 2 ) n . Silane loss and gaseous product formation were analyzed using a mass spectrometer. The hydrogen content in solid product was analyzed by the methods of IR-spectroscopy and hydrogen evolution. Based on a simple kinetic scheme we qualitatively explained the experimental dependencies of silane conversion and disilane formation, the effective activation energy of the decomposition process, and the amount of polyhydride groups in the solid product on reaction time and initial silane concentration.

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Section: On Heterogeneous Decomposition Of Silane Disilane and Trismentioning

confidence: 99%

Studying of silane thermal decomposition mechanism

Onischuk

Strunin

Ushakova

et al. 1998

Int. J. Chem. Kinet.

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“…Complete desorption of hydrogen from the formed, presumably very unstable, compounds up to monohydride species will indeed result in a surface with the same amount of active Si-H sites for all three silanes at the beginning of each pulse. However, this need not necessarily be true, as can be inferred from literature on plasma-free CVD growth of hydrogenated amorphous silicon layers [28]. These layers were grown in the same temperature region in which the TAP experiments have been performed.…”

Section: Adsorption Of Silanes At Low Temperaturesmentioning

confidence: 99%

The adsorption of silane, disilane and trisilane on polycrystalline silicon: a transient kinetic study

1996

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“…Alternatively, using higher order silanes, via CVD and PECVD resulted in incremental benefits to deposition temperature, rate and efficiency at the lab-scale. This approach has not yet been scaled to manufacturing levels, possibly due to the inconsistency in silane vaporization [3][4][5][6][7][8]. For an example, Chung et al, studied Si film deposition using neopentasilane (NPS) via lowpressure CVD, and found enhanced growth rates [4].…”

Section: Introductionmentioning

confidence: 99%

Aerosol assisted atmospheric pressure chemical vapor deposition of silicon thin films using liquid cyclic hydrosilanes

et al. 2015

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Silicon (Si) thin films were produced using an aerosol assisted atmospheric pressure chemical vapor deposition technique with liquid hydrosilane precursors cyclopentasilane (CPS, Si 5 H 10) and cyclohexasilane (CHS, Si 6 H 12). Thin films were deposited at temperatures between 300-500 °C, with maximum observed deposition rates of 55 and 47 nm/s for CPS and CHS, respectively, at 500 °C. Atomic force microscopic analysis of the films depicts smooth surfaces with roughness of 4-8 nm. Raman spectroscopic analysis indicates that the Si films deposited at 300 °C and 350 °C consist of a hydrogenated amorphous Si (a-Si:H) phase while the films deposited at 400, 450, and 500 °C are comprised predominantly of a hydrogenated nanocrystalline Si (nc-Si:H) phase. The wide optical bandgaps of 2-2.28 eV for films deposited at 350-400 °C and 1.7-1.8 eV for those deposited at 450-500 °C support the Raman data and depict a transition from a-Si:H to nc-Si:H. Films possessing the highest photosensitivity of 10 2-10 3 under AM 1.5G illumination. Based on the growth model developed for other silanes, we present a possible mechanism that governs the film growth using CPS and CHS.

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Chemical Vapor Deposition of Amorphous Silicon Using Tetrasilane

Cited by 25 publications

References 24 publications

Studying of silane thermal decomposition mechanism

Studying of silane thermal decomposition mechanism

The adsorption of silane, disilane and trisilane on polycrystalline silicon: a transient kinetic study

Aerosol assisted atmospheric pressure chemical vapor deposition of silicon thin films using liquid cyclic hydrosilanes

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