TY - JOUR
T1 - Quantum Monte Carlo calculations of the one-body density matrix and excitation energies of silicon
AU - Kent, P.
AU - Hood, Randolph Q.
AU - Towler, M.
AU - Needs, R.
AU - Rajagopal, G.
PY - 1998
Y1 - 1998
N2 - Quantum Monte Carlo (QMC) techniques are used to calculate the one-body density matrix and excitation energies for the valence electrons of bulk silicon. The one-body density matrix and energies are obtained from a Slater-Jastrow wave function with a determinant of local-density approximation (LDA) orbitals. The QMC density matrix evaluated in a basis of LDA orbitals is strongly diagonally dominant. The natural orbitals obtained by diagonalizing the QMC density matrix resemble the LDA orbitals very closely. Replacing the determinant of LDA orbitals in the wave function by a determinant of natural orbitals makes no significant difference to the quality of the wave function’s nodal surface, leaving the diffusion Monte Carlo energy unchanged. The extended Koopmans’s theorem for correlated wave functions is used to calculate excitation energies for silicon, which are in reasonable agreement with the available experimental data. A diagonal approximation to the theorem, evaluated in the basis of LDA orbitals, works quite well for both the quasihole and quasielectron states. We have found that this approximation has an advantageous scaling with system size, allowing more efficient studies of larger systems.
AB - Quantum Monte Carlo (QMC) techniques are used to calculate the one-body density matrix and excitation energies for the valence electrons of bulk silicon. The one-body density matrix and energies are obtained from a Slater-Jastrow wave function with a determinant of local-density approximation (LDA) orbitals. The QMC density matrix evaluated in a basis of LDA orbitals is strongly diagonally dominant. The natural orbitals obtained by diagonalizing the QMC density matrix resemble the LDA orbitals very closely. Replacing the determinant of LDA orbitals in the wave function by a determinant of natural orbitals makes no significant difference to the quality of the wave function’s nodal surface, leaving the diffusion Monte Carlo energy unchanged. The extended Koopmans’s theorem for correlated wave functions is used to calculate excitation energies for silicon, which are in reasonable agreement with the available experimental data. A diagonal approximation to the theorem, evaluated in the basis of LDA orbitals, works quite well for both the quasihole and quasielectron states. We have found that this approximation has an advantageous scaling with system size, allowing more efficient studies of larger systems.
UR - http://www.scopus.com/inward/record.url?scp=0000036409&partnerID=8YFLogxK
U2 - 10.1103/PhysRevB.57.15293
DO - 10.1103/PhysRevB.57.15293
M3 - Article
AN - SCOPUS:0000036409
SN - 1098-0121
VL - 57
SP - 15293
EP - 15302
JO - Physical Review B - Condensed Matter and Materials Physics
JF - Physical Review B - Condensed Matter and Materials Physics
IS - 24
ER -