Add to ORKGElectronic band structure of various crystal orientations of relaxed and strained bulk, 1D and 2D confined semiconductors are investigated using nonlocal empirical pseudopotential method with spin-orbit interaction. For the bulk semiconductors, local and nonlocal pseudopotential parameters are obtained by fitting transport-relevant quantities, such as band gap, effective masses and deformation potentials, to available experimental data. A cubic-spline interpolation is used to extend local form factors to arbitrary q and the resulting transferable local pseudopotential V(q) with correct work function is used to investigate the 1D and 2D confined systems with supercell method. Quantum confinement, uniaxial and biaxial strain and crystal orien...
We have calculated band-edge energies for most combinations of zinc blende AlN, GaN, InN, GaP, GaAs,...
In this thesis the conductivity of strained materials has been investigated using density functional...
Quantum dots in nanowires grow on a (111) substrate and it is expected that the modifications of the...
Electronic band structure of various crystal orientations of relaxed and strained bulk, 1D and 2D co...
Analytical and finite‐element‐method calculations have been conducted for obtaining strain distribut...
Analytical and finite‐element‐method calculations have been conducted for obtaining strain distribut...
Results of first-principles full potential calculations of absolute position of valence and conducti...
The effects of the strain caused by lattice mismatched epitaxy on the electronic bandstructure of se...
The effects of the strain caused by lattice mismatched epitaxy on the electronic bandstructure of se...
A strain Hamiltonian Hst, associated with a sps * k. p Hamiltonian Hkp, is used to describe the vale...
The properties of a semiconductor are drastically modified when the crystal point group symmetry is ...
The impact of uni-axial compressive and tensile strain and diameter on the electronic band structure...
We present a practical approach to calculate the complex band structure of an electrode for quantum ...
We present a practical approach to calculate the complex band structure of an electrode for quantum ...
Strained-layer heterojunctions and superlattices have recently shown tremendous potential for device...
We have calculated band-edge energies for most combinations of zinc blende AlN, GaN, InN, GaP, GaAs,...
In this thesis the conductivity of strained materials has been investigated using density functional...
Quantum dots in nanowires grow on a (111) substrate and it is expected that the modifications of the...
Electronic band structure of various crystal orientations of relaxed and strained bulk, 1D and 2D co...
Analytical and finite‐element‐method calculations have been conducted for obtaining strain distribut...
Analytical and finite‐element‐method calculations have been conducted for obtaining strain distribut...
Results of first-principles full potential calculations of absolute position of valence and conducti...
The effects of the strain caused by lattice mismatched epitaxy on the electronic bandstructure of se...
The effects of the strain caused by lattice mismatched epitaxy on the electronic bandstructure of se...
A strain Hamiltonian Hst, associated with a sps * k. p Hamiltonian Hkp, is used to describe the vale...
The properties of a semiconductor are drastically modified when the crystal point group symmetry is ...
The impact of uni-axial compressive and tensile strain and diameter on the electronic band structure...
We present a practical approach to calculate the complex band structure of an electrode for quantum ...
We present a practical approach to calculate the complex band structure of an electrode for quantum ...
Strained-layer heterojunctions and superlattices have recently shown tremendous potential for device...
We have calculated band-edge energies for most combinations of zinc blende AlN, GaN, InN, GaP, GaAs,...
In this thesis the conductivity of strained materials has been investigated using density functional...
Quantum dots in nanowires grow on a (111) substrate and it is expected that the modifications of the...