Add to ORKGJournal ArticleThe equilibrium thermal roughening of thin Ge layers (one and two monolayers) deposited on Si(001) has been investigated with low-energy electron microscopy. A Ge-coverage-dependent roughening is observed. For two monolayers, the temperature at which imaging contrast is lost due to surface roughness is 900 ± 25 ◦C, between the roughening temperatures of Ge(001) and Si(001). Lower Ge coverages move this temperature closer to that of Si(001). The roughening is confined to the Ge overlayers. It is believed that this phenomenon represents a new type of surface roughening transition that should be generally applicable for heteroepitaxial films
The low temperature homoepitaxial growth of silicon has been probed in situ by Reflection High Energ...
The results of STM and RHEED studies of a thin Ge film grown on the Si/Si(001) epitaxial layers with...
Molecular beam epitaxy of germanium was used along with kinetic Monte Carlo simulations to study tim...
In this work, we investigate interface roughness effects on the energetic terms that play a key role...
Low temperature film growth involves a competition between the energetics and kinetics of atom motio...
Ag(100) homoepitaxy constitutes one of the simplest systems in which to study thin-film growth. Yet ...
We investigated the thickness dependence of the thermal capacitance of thin films with evolving boun...
Reflection high energy electron diffraction (RHEED) was used to investigate surface roughening durin...
We present comprehensive experimental results on the fashion in which the Ge(001) surface roughens a...
We investigate the influence of roughness at a nanometer scale on the thermal properties of thin fil...
Texto completo: acesso restrito. p. 1-19We study the effects of time-dependent substrate/film temper...
The low temperature homoepitaxial growth of silicon has been probed in situ by Reflection High Energ...
The possibility of roughness reducing of the Ge/Si (100) film using low-temperature layer of Ge (LT-...
Deformation mechanisms involving mass transport by stress driven diffusion influence a large number ...
Growth front roughening characteristics of vacuum deposited pentamer 2,5-di-n-octyloxy-1,4-bis[4-(st...
The low temperature homoepitaxial growth of silicon has been probed in situ by Reflection High Energ...
The results of STM and RHEED studies of a thin Ge film grown on the Si/Si(001) epitaxial layers with...
Molecular beam epitaxy of germanium was used along with kinetic Monte Carlo simulations to study tim...
In this work, we investigate interface roughness effects on the energetic terms that play a key role...
Low temperature film growth involves a competition between the energetics and kinetics of atom motio...
Ag(100) homoepitaxy constitutes one of the simplest systems in which to study thin-film growth. Yet ...
We investigated the thickness dependence of the thermal capacitance of thin films with evolving boun...
Reflection high energy electron diffraction (RHEED) was used to investigate surface roughening durin...
We present comprehensive experimental results on the fashion in which the Ge(001) surface roughens a...
We investigate the influence of roughness at a nanometer scale on the thermal properties of thin fil...
Texto completo: acesso restrito. p. 1-19We study the effects of time-dependent substrate/film temper...
The low temperature homoepitaxial growth of silicon has been probed in situ by Reflection High Energ...
The possibility of roughness reducing of the Ge/Si (100) film using low-temperature layer of Ge (LT-...
Deformation mechanisms involving mass transport by stress driven diffusion influence a large number ...
Growth front roughening characteristics of vacuum deposited pentamer 2,5-di-n-octyloxy-1,4-bis[4-(st...
The low temperature homoepitaxial growth of silicon has been probed in situ by Reflection High Energ...
The results of STM and RHEED studies of a thin Ge film grown on the Si/Si(001) epitaxial layers with...
Molecular beam epitaxy of germanium was used along with kinetic Monte Carlo simulations to study tim...