Author:
Publisher:
ISBN:
Category :
Languages : en
Pages :
Book Description
H-Mediated Film Growth and Dopant Incorporation Kinetics During Silicon Germanium(001):boron Gas-Source Molecular Beam Epitaxy
Ultra-high B Doping During Si1̳-̳x̳Gex̳(001) Gas-source Molecular-beam Epitaxy
Growth Kinetics of III-V Semiconductor Thin Films by Molecular Beam Epitaxy with Gas Sources
B-incorporation Kinetics and Charge Transport Property of Silicon Germanide(001) Layer Grown by GS-MBE from Silicon Hydride, Germanium Hydride, and Boron Hydride
Author: Qing Lu
Publisher:
ISBN:
Category :
Languages : en
Pages :
Book Description
The growth rates of Si(001) and Ge(001) by gas-source molecular-beam epitaxy (GS-MBE) from $\rm Si\sb2H\sb6$ and $\rm Ge\sb2H\sb6$ as a function of T$\sb{\rm s}$ are well described by a model based upon dissociative $\rm Si\sb2H\sb6$ and $\rm Ge\sb2H\sb6$ chemisorption followed by a series of surface decomposition reactions with the rate-limiting step being first-order hydrogen desorption from Si and Ge monohydride for which the activation energy is 2.04 and 1.56 eV, respectively. The zero-coverage reactive sticking probability of $\rm Si\sb2H\sb6$ on Si(001)2 x 1 ($\rm Ge\sb2H\sb6$ on Ge(001)2 x 1) in the impingement-flux-limited growth regime was found to be $\rm S\sbsp{Si\sb2H\sb6}{Si} = 0.036\ (S\sbsp{Ge\sb2H\sb6}{Ge} = 0.052).$ The growth rate of $\rm Si\sb{1-x}Ge\sb{x}$ alloys R$\sb{\rm SiGe}$ decreases somewhat with increasing $\rm G\sb2H\sb6$ in the flux-limited growth mode while dramatically increasing $\rm R\sb{SiGe}$ in the surface-reaction-limited regime.
Publisher:
ISBN:
Category :
Languages : en
Pages :
Book Description
The growth rates of Si(001) and Ge(001) by gas-source molecular-beam epitaxy (GS-MBE) from $\rm Si\sb2H\sb6$ and $\rm Ge\sb2H\sb6$ as a function of T$\sb{\rm s}$ are well described by a model based upon dissociative $\rm Si\sb2H\sb6$ and $\rm Ge\sb2H\sb6$ chemisorption followed by a series of surface decomposition reactions with the rate-limiting step being first-order hydrogen desorption from Si and Ge monohydride for which the activation energy is 2.04 and 1.56 eV, respectively. The zero-coverage reactive sticking probability of $\rm Si\sb2H\sb6$ on Si(001)2 x 1 ($\rm Ge\sb2H\sb6$ on Ge(001)2 x 1) in the impingement-flux-limited growth regime was found to be $\rm S\sbsp{Si\sb2H\sb6}{Si} = 0.036\ (S\sbsp{Ge\sb2H\sb6}{Ge} = 0.052).$ The growth rate of $\rm Si\sb{1-x}Ge\sb{x}$ alloys R$\sb{\rm SiGe}$ decreases somewhat with increasing $\rm G\sb2H\sb6$ in the flux-limited growth mode while dramatically increasing $\rm R\sb{SiGe}$ in the surface-reaction-limited regime.
Silicon (011) and Silicon Germanium (011) Gas-Source Molecular Beam Epitaxy: Surface Reconstructions, Growth Kinetics, and Germanium Segregation
Growth Processes and Surface Phase Equilibria in Molecular Beam Epitaxy
Author: Nikolai N. Ledentsov
Publisher: Springer Science & Business Media
ISBN: 9783540657941
Category : Technology & Engineering
Languages : en
Pages : 114
Book Description
The book considers the main growth-related phenomena occurring during epitaxial growth, such as thermal etching, doping, segregation of the main elements and impurities, coexistence of several phases at the crystal surface and segregation-enhanced diffusion. It is complete with tables, graphs and figures, which allow fast determination of suitable growth parameters for practical applications.
Publisher: Springer Science & Business Media
ISBN: 9783540657941
Category : Technology & Engineering
Languages : en
Pages : 114
Book Description
The book considers the main growth-related phenomena occurring during epitaxial growth, such as thermal etching, doping, segregation of the main elements and impurities, coexistence of several phases at the crystal surface and segregation-enhanced diffusion. It is complete with tables, graphs and figures, which allow fast determination of suitable growth parameters for practical applications.
Growth Kinetics of Silicon Films
Rapid Thermal Vapor Phase Epitaxy
Development of Metalorganic Molecular Beam Epitaxy for the Growth of Indium(0.53) Gallium(0.47) Arsenic/indium Phosphide Heterojunction Bipolar Transistors and Quantum Well Optoelectronic Devices
Author: Steven Lee Jackson
Publisher:
ISBN:
Category :
Languages : en
Pages :
Book Description
Metalorganic molecular beam epitaxy (MOMBE) offers several potential advantages over molecular beam epitaxy (MBE) and metalorganic chemical vapor deposition (MOCVD) for the development of high-speed/reliability C-doped In$\rm\sb{0.53}Ga\sb{0.47}$As/InP heterojunction bipolar transistors (HBTs). Improvements in reproducibility of alloy composition and layer thickness for $\rm In\sb xGa\sb{1-x}As$ and InP, which are afforded by MOMBE relative to MBE, offer clear advantages for manufacturing. The potential for reduction of the H passivation of C acceptors and substrate temperature sensitivity of the alloy composition, using CCl$\sb4$ as the C source, offers advantages relative to MOCVD. However, the lack of an efficient gaseous n-type dopant source limits the potential for scalability of MOMBE. This thesis describes recent work on the development of MOMBE for the growth of C-doped $\rm In\sb{0.53}Ga\sb{0.47}As/InP$ HBTs. Issues relevant to obtaining abrupt heterointerfaces, the development of a new gaseous Si dopant source, SiBr$\sb4$, and the sources of H passivation of C acceptors in C-doped $\rm In\sb{0.53}Ga\sb{0.47}As$ have been investigated. The use of a common Ta-baffled hydride cracker for the dissociation of AsH$\sb3$ and PH$\sb3$ at 950$\sp\circ$C was found to result in the generation of As$\sb2$, P$\sb2$, and H$\sb2$. However, severe group V memory effects were observed for P and As. Significantly faster switching was obtained, by using separate open Ta tube crackers. Single and multiple quantum well $\rm In\sb{0.53}Ga\sb{0.47}As/InP$ heterostructures containing quantum wells as narrow as 10 A exhibit intense photoluminescence and ninth order satellite peaks in resolution x-ray diffraction rocking curves. SiBr$\sb4$ has been demonstrated as an extremely efficient gaseous Si doping source which is compatible with MOMBE. Net electron concentrations of n = $\rm2.3\times10\sp{20}\ cm\sp{-3}$ have been obtained in InP grown at 450$\sp\circ$C without morphology degradation. Specific contact resistances of $\rm\rho\sb c=6\times10\sp{-8}\ \Omega$-cm$\sp{2}$ have been obtained by using nonalloyed Ti/Pt/Au contacts directly to these heavily-doped InP layers. $\rm In\sb{0.53}Ga\sb{0.47}As/InP$ HBTs using InP contact layers with comparably low specific contact resistances have been demonstrated. A blue shift in the photoluminescence peak energy of approximately 265 meV is observed for InP layers doped to n = $\rm7\times10\sp{19}\ cm\sp{-3}.$ Carbon doping of $\rm In\sb{0.53}Ga\sb{0.47}As$ in gas source molecular beam epitaxy and MOMBE using CCl$\sb4$ has been investigated. Net hole concentrations of p = $\rm1.8\times10\sp{20}\ cm\sp{-3}$ have been obtained with negligible H passivation for hole concentrations as high as p = $\rm8\times10\sp{19}\ cm\sp{-3}$. The degree of H passivation was found to be highly dependent on the AsH$\sb3$ cracking temperature with an enhanced effect at substrate temperatures ${
Publisher:
ISBN:
Category :
Languages : en
Pages :
Book Description
Metalorganic molecular beam epitaxy (MOMBE) offers several potential advantages over molecular beam epitaxy (MBE) and metalorganic chemical vapor deposition (MOCVD) for the development of high-speed/reliability C-doped In$\rm\sb{0.53}Ga\sb{0.47}$As/InP heterojunction bipolar transistors (HBTs). Improvements in reproducibility of alloy composition and layer thickness for $\rm In\sb xGa\sb{1-x}As$ and InP, which are afforded by MOMBE relative to MBE, offer clear advantages for manufacturing. The potential for reduction of the H passivation of C acceptors and substrate temperature sensitivity of the alloy composition, using CCl$\sb4$ as the C source, offers advantages relative to MOCVD. However, the lack of an efficient gaseous n-type dopant source limits the potential for scalability of MOMBE. This thesis describes recent work on the development of MOMBE for the growth of C-doped $\rm In\sb{0.53}Ga\sb{0.47}As/InP$ HBTs. Issues relevant to obtaining abrupt heterointerfaces, the development of a new gaseous Si dopant source, SiBr$\sb4$, and the sources of H passivation of C acceptors in C-doped $\rm In\sb{0.53}Ga\sb{0.47}As$ have been investigated. The use of a common Ta-baffled hydride cracker for the dissociation of AsH$\sb3$ and PH$\sb3$ at 950$\sp\circ$C was found to result in the generation of As$\sb2$, P$\sb2$, and H$\sb2$. However, severe group V memory effects were observed for P and As. Significantly faster switching was obtained, by using separate open Ta tube crackers. Single and multiple quantum well $\rm In\sb{0.53}Ga\sb{0.47}As/InP$ heterostructures containing quantum wells as narrow as 10 A exhibit intense photoluminescence and ninth order satellite peaks in resolution x-ray diffraction rocking curves. SiBr$\sb4$ has been demonstrated as an extremely efficient gaseous Si doping source which is compatible with MOMBE. Net electron concentrations of n = $\rm2.3\times10\sp{20}\ cm\sp{-3}$ have been obtained in InP grown at 450$\sp\circ$C without morphology degradation. Specific contact resistances of $\rm\rho\sb c=6\times10\sp{-8}\ \Omega$-cm$\sp{2}$ have been obtained by using nonalloyed Ti/Pt/Au contacts directly to these heavily-doped InP layers. $\rm In\sb{0.53}Ga\sb{0.47}As/InP$ HBTs using InP contact layers with comparably low specific contact resistances have been demonstrated. A blue shift in the photoluminescence peak energy of approximately 265 meV is observed for InP layers doped to n = $\rm7\times10\sp{19}\ cm\sp{-3}.$ Carbon doping of $\rm In\sb{0.53}Ga\sb{0.47}As$ in gas source molecular beam epitaxy and MOMBE using CCl$\sb4$ has been investigated. Net hole concentrations of p = $\rm1.8\times10\sp{20}\ cm\sp{-3}$ have been obtained with negligible H passivation for hole concentrations as high as p = $\rm8\times10\sp{19}\ cm\sp{-3}$. The degree of H passivation was found to be highly dependent on the AsH$\sb3$ cracking temperature with an enhanced effect at substrate temperatures ${
Study of Thin Film Growth Kinetics of Homoepitaxy by Molecular Beam Epitaxy and Pulsed Laser Deposition
Author: Byungha Shin
Publisher:
ISBN: 9780549036517
Category :
Languages : en
Pages : 184
Book Description
First, we have conducted a systematic investigation of the phase shift of the RHEED intensity oscillations during Ge(001) homoepitaxy MBE for a wide range of diffraction conditions. We conclude that the phase shift is caused by the overlap of the specular spot and the Kikuchi features, in contrast to models involving dynamical scattering theory for the phase shift.
Publisher:
ISBN: 9780549036517
Category :
Languages : en
Pages : 184
Book Description
First, we have conducted a systematic investigation of the phase shift of the RHEED intensity oscillations during Ge(001) homoepitaxy MBE for a wide range of diffraction conditions. We conclude that the phase shift is caused by the overlap of the specular spot and the Kikuchi features, in contrast to models involving dynamical scattering theory for the phase shift.