Presentation is loading. Please wait.

Presentation is loading. Please wait.

Calculation of matrix elements José M. Soler Universidad Autónoma de Madrid.

Published byGwendoline Freeman Modified over 9 years ago

Similar presentations

Presentation on theme: "Calculation of matrix elements José M. Soler Universidad Autónoma de Madrid."— Presentation transcript:

1 Calculation of matrix elements José M. Soler Universidad Autónoma de Madrid

2 Schrödinger equation H  i (r) = E i  i (r)  i (r) =   c i    (r)  (H  - E i S  )c i = 0 H  = S  =

3 Kohn-Sham hamiltonian H = T + V PS + V H (r) + V xc (r) T = -(1/2)  2 V PS = V ion (r) + V nl V ion (r)  - Z val / r Local pseudopotentiual V nl =   |   >   <   | Kleinman-Bylander V H (r) =  dr’  (r’) / |r-r’| Hartree potential V xc (r) = v xc (  (r)) Exchange & correlation

4 Long-range potentials H = T + V ion (r) + V nl + V H (r) + V xc (r) Long range  V H (r) = V H [  SCF (r)] - V H [  atoms (r)] V na (r) = V ion (r) + V H [  atoms (r)] Neutral-atom potential H = T + V nl + V na (r) +  V H (r) + V xc (r) Two-center integrals Grid integrals

5 Sparsity KB pseudopotential projector Basis orbitals Non-overlap interactions 1 2 3 4 5 1 with 1 and 2 2 with 1,2,3, and 5 3 with 2,3,4, and 5 4 with 3,4 and 5 5 with 2,3,4, and 5 S  and H  are sparse   is not strictly sparse but only a sparse subset is needed

6 Two-center integrals Convolution theorem

7 Atomic orbitals

8 Overlap and kinetic matrix elements K 2 max = 2500 Ry Integrals by special radial-FFT S lm (R) and T lm (R) calculated and tabulated once and for all

9 Real spherical harmonics

10 Grid work FFT

11 Poisson equation  2 V H (r) = - 4   (r)  (r) =  G  G e iGr  V H (r) =  G V G e iGr V G = - 4   G / G 2  (r)   G  V G  V H (r) FFT

12 GGA

13 Egg-box effect Affects more to forces than to energy Grid-cell sampling E x Grid points Orbital/atom

14 Grid fineness: energy cutoff  x  k c =  /  x  E cut =h 2 k c 2 /2m e

15 Grid fineness convergence

16 Points and subpoints Sparse storage: (i,  i ) Points (index and value stored) Subpoints (value only)  x  E cut

17 Extended mesh 46546 1 321 3 4 654 6 13213 54321 109876 1514131211 2019181716 1  7  8,12,13  2,4,5 6  14  15,19,20  4,3,1 +1,+5,+6

18 Forces and stress tensor Analytical: e.g. Calculated only in the last SCF iteration

Download ppt "Calculation of matrix elements José M. Soler Universidad Autónoma de Madrid."

Similar presentations

Spin order in correlated electron systems

Spin order in correlated electron systems
Take-home postcard. Basis set: Atomic orbitals s p d f SIESTA: Strictly localized (zero beyond cut-off radius)

Take-home postcard. Basis set: Atomic orbitals s p d f SIESTA: Strictly localized (zero beyond cut-off radius)
0 Jack SimonsJack Simons, Henry Eyring Scientist and Professor Chemistry Department University of Utah Electronic Structure Theory Session 7.

0 Jack SimonsJack Simons, Henry Eyring Scientist and Professor Chemistry Department University of Utah Electronic Structure Theory Session 7.
Hartree – Fock Benchmark JOHN FEO Center for Adaptive Supercomputing Software.

Hartree – Fock Benchmark JOHN FEO Center for Adaptive Supercomputing Software.
The H 2 molecule without convergence studies Objectives: - the (pseudo)total energy - the bond length r HH Acknowledgment: exercise inspired on the first.

The H 2 molecule without convergence studies Objectives: - the (pseudo)total energy - the bond length r HH Acknowledgment: exercise inspired on the first.
Modelling of Defects DFT and complementary methods

Modelling of Defects DFT and complementary methods
Systematics for realistic proyects: from quick & dirty to converged calculations José M. Soler and Alberto García.

Systematics for realistic proyects: from quick & dirty to converged calculations José M. Soler and Alberto García.
Pseudopotentials and Basis Sets

Pseudopotentials and Basis Sets
Molecular Bonding Molecular Schrödinger equation

Molecular Bonding Molecular Schrödinger equation
Javier Junquera Code structure: calculation of matrix elements of H and S. Direct diagonalization José M. Soler = N  N N  1.

Javier Junquera Code structure: calculation of matrix elements of H and S. Direct diagonalization José M. Soler = N  N N  1.
Introduction to Molecular Orbitals

Introduction to Molecular Orbitals
Chapter 3 Electronic Structures

Chapter 3 Electronic Structures
The Nuts and Bolts of First-Principles Simulation

The Nuts and Bolts of First-Principles Simulation
Transport Calculations with TranSIESTA

Transport Calculations with TranSIESTA
Single Particle Energies

Single Particle Energies
09-1 Physics I Class 09 Potential Energy and Conservation of Energy.

09-1 Physics I Class 09 Potential Energy and Conservation of Energy.
Norm-conserving pseudopotentials in electronic structure calculations Javier Junquera Alberto García.

Norm-conserving pseudopotentials in electronic structure calculations Javier Junquera Alberto García.
Generalized Scattering Matrix Method for Electrostatic Force Microscopy Sacha Gómez Moñivas and Juan José Sáenz Gutiérrez Universidad Autónoma de Madrid.

Generalized Scattering Matrix Method for Electrostatic Force Microscopy Sacha Gómez Moñivas and Juan José Sáenz Gutiérrez Universidad Autónoma de Madrid.
Thermal properties from first principles with the use of the Free Energy Surface concept Dr inż. Paweł Scharoch Institute of Physics, Wroclaw University.

Thermal properties from first principles with the use of the Free Energy Surface concept Dr inż. Paweł Scharoch Institute of Physics, Wroclaw University.
Efficient factorization of van der Waals DFT functional Guillermo Roman and Jose M. Soler Departamento de Física de la Materia Condensada Universidad Autónoma.

Efficient factorization of van der Waals DFT functional Guillermo Roman and Jose M. Soler Departamento de Física de la Materia Condensada Universidad Autónoma.

Similar presentations

Ads by Google