Simulating Correlations with Computers: Lecture Notes of the Autumn School on Correlated Electrons 2021 3958065295, 9783958065291
244 5 19MB
English Pages [416] Year 2021
Koch
Many-electron states
Second quantization
Creation and annihilation operators
Representation of Slater determinants
Representation of n-body operators
Transforming the orbital basis
Exact diagonalization
Variational principles
Matrix eigenvalue problem
Dimension of the Hilbert space and sparseness
Non-interacting electrons
Jordan-Wigner representation
Spins, hard-core bosons, and fermions
Appendix
Atomic units
Non-orthonormal basis
Pauli matrices
Some useful commutation relations
Doll
Introduction
Setting up the Hamiltonian
Quantum chemical approach
Hartree-Fock
Hartree-Fock equations
Finite basis set: Hartree-Fock-Roothaan
Solution of the Hartree-Fock equations
Density functional theory
Basis sets
Beyond Hartree-Fock: electron correlation
Second Quantization
Wave function based correlation
Properties
Examples
Conclusion
Burke
Introduction
Background
Hubbard dimer
Density functional theory
Hohenberg-Kohn I
Hohenberg-Kohn II
Hohenberg-Kohn III
Kohn-Sham DFT
KS spectral function
The ionization potential theorem
Mind the gap
Talking about ground-state DFT
Time-dependent DFT (TDDFT)
Hubbard dimer
Talking about TDDFT
Summary
Exercises
Romaniello
Introduction
Theoretical background: the GW approximation & beyond
GW
Vertex corrections
The Hubbard dimer
Exact solution
GW
T-matrix
Conclusions and outlook
Solutions for 2+/-1 electrons
One electron
Two electrons
Three electrons
Pavarini
Introduction
From DMFT to LDA+DMFT
DMFT for a toy model: The Hubbard dimer
Non-local Coulomb interaction
Quantum-impurity solvers: Continuous-time quantum Monte Carlo
Hartree-Fock versus DMFT approximation
DMFT for the one-band Hubbard model
DMFT for multi-orbital models
Building materials-specific many-body models
Model construction
Localization of the basis and range of the Coulomb interaction
Hubbard Hamiltonians for t2g and eg systems
Spin-orbit interaction and effects of the basis choice
Non-spherical Coulomb terms and double-counting correction
Conclusion
Eigenstates of two-site models
Hubbard dimer
Anderson molecule
Lehmann representation of the local Green function
Eder
Introduction
Green functions and the self-energy
The Green function and its analytical properties
The self-energy and its analytical properties
Physical significance of the self-energy
The Luttinger-Ward functional
The Green function as a functional integral
Construction of the Luttinger-Ward functional
Self-energy functional theories
Dynamical mean-field theory
Metal-insulator-transition in a dimer
Summary and conclusion
Janis
Introduction – Renormalization of the many-body perturbation theory
Generic models of interacting electrons and quantum perturbations
Static renormalizations
Variational mean-field theories
Fermi liquid
Dynamical corrections and Green functions
Green functions, Matsubara formalism, and analytic continuation
One-particle Green function – Schwinger and Dyson equations
Two-particle vertex – Bethe-Salpeter equations
Baym-Kadanoff construction of the renormalized perturbation theory
Generating Luttinger-Ward functional and irreducible functions
Schwinger-Dyson equation, Ward identity, and Schwinger field-theory
Simple approximations: Hartree, RPA, FLEX
Two-particle approach and two-particle renormalizations
Symmetry-breaking field – odd and even functions
Two-particle self-consistency and charge renormalization
Order parameter and mass renormalization
Mean-field theory with a two-particle self-consistency
Reduced parquet equations
Spectral function
Conclusions
Stefanucci
Introduction
The contour idea
Nonequilibrium Green function
Noninteracting systems
Dyson equation on the contour
Simple diagrammatic approximations
Kadanoff-Baym equations
The Generalized Kadanoff-Baym Ansatz
Time-linear scaling and state-of-the-art approximations
First-principles NEGF+GKBA implementations
Kohn-Sham basis
Localized basis
Schilling
Introduction
Concept of correlation and entanglement
The quantum information theoretical formalism
Fermionic quantum systems
Superselection rules
Analytic treatment
Closed formulas for entanglement and correlation
Single electron state
Dissociated hydrogen
Hubbard dimer
Numerical application to molecular ground states
Computational details
Single-orbital entanglement and correlation
Orbital-orbital entanglement and correlation
Hofstetter
Introduction
Optical lattice emulation of the Hubbard model
Mott insulator transition
Quantum magnetic correlations
Topological (many-body) states of ultracold atoms
Disorder and localization
Outlook
Michielsen
Introduction
Gate-based quantum computing
Quantum bits and gates
Programming and simulating quantum circuits
Example: Quantum adder
Example: Quantum approximate optimization algorithm
Quantum annealing
Optimization problems with binary variables
Working principle of a quantum annealer
Architecture of D-Wave quantum annealers
Limitations
Programming a D-Wave quantum annealer
Example: Garden optimization
JUQCS standard gate set
Veis
Introduction
Quantum computing in a nutshell
Qubit-based circuit model
Quantum simulation
Quantum chemistry in a nutshell
Hartree-Fock method
Correlation energy
Second quantization
Quantum chemistry to quantum computing mappings
First quantized methods
Second quantized methods
Quantum algorithms for quantum chemistry
Phase estimation
Variational quantum-classical algorithms
Summary
DiVincenzo
Quantum computing science is everywhere
My main thesis
Electron theory for qubits
Other spin-orbit terms
A few thoughts about electron-electron interaction for spin qubits
Index
Recommend Papers
- Author / Uploaded
- Eva Pavarini
- Erik Koch
File loading please wait...
Citation preview
Eva Pavarini and Erik Koch (Eds.)
Simulating Correlations with Computers
Modeling and Simulation
Simulating Correlations with Computers Eva Pavarini and Erik Koch (Eds.)
Modeling and Simulation Band / Volume 11 ISBN 978-3-95806-529-1
ISBN 978-3-95806-529-1
9 783958 065291
11
Schriften des Forschungszentrums Jülich Reihe Modeling and Simulation
Band / Volume 11
Forschungszentrum Jülich GmbH Institute for Advanced Simulation
Lecture Notes of the Autumn School on Correlated Electrons 2021 Eva Pavarini and Erik Koch (Eds.)
Simulating Correlations with Computers Autumn School organized by the Institute for Advanced Simulation at Forschungszentrum Jülich 20 – 24 September 2021
Schriften des Forschungszentrums Jülich Modeling and Simulation ISSN 2192-8525
Band / Volume 11 ISBN 978-3-95806-529-1
Bibliographic information published by the Deutsche Nationalbibliothek. Die Deutsche Nationalbibliothek lists this publication in the Deutsche Nationalbibliografie; detailed bibliographic data are available in the Internet at http://dnb.d-nb.de.
Publisher: Cover Design:
Forschungszentrum Jülich GmbH Institute for Advanced Simulation
Printer:
Schloemer & Partner GmbH, Düren
Copyright:
Forschungszentrum Jülich 2021
Grafische Medien, Forschungszentrum Jülich GmbH
Distributor: Forschungszentrum Jülich Zentralbibliothek, Verlag 52425 Jülich Phone +49 (0)2461 61-5368 · Fax +49 (0)2461 61-6103 e-mail: [email protected] www.fz-juelich.de/zb Schriften des Forschungszentrums Jülich Reihe Modeling and Simulation, Band / Volume 11 ISSN 2192-8525 ISBN 978-3-95806-529-1 Vollständig frei verfügbar über das Publikationsportal des Forschungszentrums Jülich (JuSER) unter www.fz-juelich.de/zb/openaccess
This is an Open Access publication distributed under the terms of the Creative Commons Attribution License 4.0, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.
Contents Preface 1. Second Quantization and Jordan-Wigner Representations Erik Koch 2. Fundamentals of Quantum Chemistry Klaus Doll 3. Lies My Teacher Told Me About Density Functional Theory: Seeing Through Them with the Hubbard Dimer Kieron Burke 4. Hubbard Dimer in GW and Beyond Pina Romaniello 5. Dynamical Mean-Field Theory for Materials Eva Pavarini 6. Green Functions and Self-Energy Functionals Robert Eder 7. Green Functions in the Renormalized Many-Body Perturbation Theory V´aclav Janiˇs 8. An Essential Introduction to NEGF Methods for Real-Time Simulations Gianluca Stefanucci 9. Orbital Entanglement and Correlation Christian Schilling 10. Analog Quantum Simulations of the Hubbard Model Walter Hofstetter 11. Programming Quantum Computers Kristel Michielsen 12. Quantum Chemistry on Quantum Computers Libor Veis 13. Quantum Computing – Quo Vadis? David DiVincenzo Index
Preface The combinatorial growth of the Hilbert space makes the many-electron problem one of the grand challenges of theoretical physics. Progress relies on the development of non-perturbative methods, based on either wavefunctions or self energies. This made, in recent years, calculations for strongly correlated materials a reality. These simulations draw their power from three sources: theoretical advances, algorithmic developments, and the raw power of massively parallel supercomputers. Turning to quantum hardware could give quantum materials science the ultimate boost. Before quantum parallelism can be exploited, however, many questions, algorithmic and engineering, need to be addressed. This year’s school will provide students with an overview of the state-of-the-art of manybody simulations and the promises of quantum computers. After introducing the basic modeling techniques and the concept of entanglement in correlated states, lectures will turn to methods that do not rely on wavefunctions, comparing density-functional theory, the GW method and dynamical mean-field approaches. Advanced lectures will broaden the discussion, addressing topics from the Luttinger-Ward functional to non-equilibrium Green functions. As a glimpse of future possibilities, the basics of quantum computing and its possible uses in materials simulations will be outlined. A school of this size and scope requires backing from many sources. This is even more true during the Corona pandemics, which provided scores of new challenges. We are very grateful for all the practical and financial support we have received. The Institute for Advanced Simulation at the Forschungszentrum J¨ulich and the J¨ulich Supercomputer Centre provided the major part of the funding and were vital for the organization of the school as well as for the production of this book. The Institute for Complex Adaptive Matter (ICAM) supplied additional funds and ideas for successful online formats. The nature of a school makes it desirable to have the lecture notes available when the lectures are given. This way students get the chance to work through the lectures thoroughly while their memory is still fresh. We are therefore extremely grateful to the lecturers that, despite tight deadlines, provided their manuscripts in time for the production of this book. We are confident that the lecture notes collected here will not only serve the participants of the school but will also be useful for other students entering the exciting field of strongly correlated materials. We are grateful to Mrs. H. Lexis of the Verlag des Forschungszentrum J¨ulich and to Mrs. D. Mans of the Grafische Betriebe for providing their expert support in producing the present volume on a tight schedule. We heartily thank our students and postdocs who helped with proofreading the manuscripts, often on quite short notice: Elaheh Adibi, Julian Mußhoff, Neda Samani, and Xue-Jing Zhang. Finally, our special thanks go to Dipl.-Ing. R. H¨olzle for his invaluable advice on the innumerable questions concerning the organization of such an endeavor, and to Mrs. L. Snyders for expertly handling all practical issues.
Eva Pavarini and Erik Koch August 2021
1
Second Quantization and Jordan-Wigner Representations Erik Koch Julich Supercomputer Centre ¨ Forschungszentrum Julich ¨
Contents 1
Many-electron states
2
Second quantization 2.1 Creation and annihilation operators . . 2.2 Representation of Slater determinants 2.3 Representation of n-body operators . 2.4 Transforming the orbital basis . . . .
3
4
2
. . . .
5 5 7 8 12
. . . .
13 13 15 16 18
Jordan-Wigner representation 4.1 Spins, hard-core bosons, and fermions . . . . . . . . . . . . . . . . . . . . . .
18 22
. . . .
. . . .
. . . .
. . . .
. . . .
Exact diagonalization 3.1 Variational principles . . . . . . . . . . . . . . 3.2 Matrix eigenvalue problem . . . . . . . . . . . 3.3 Dimension of the Hilbert space and sparseness . 3.4 Non-interacting electrons . . . . . . . . . . . .
A Appendix A.1 Atomic units . . . . . . . . . . . . . A.2 Non-orthonormal basis . . . . . . . A.3 Pauli matrices . . . . . . . . . . . . A.4 Some useful commutation relations .
E. Pavarini and E. Koch (eds.) Simulating Correlations with Computers Modeling and Simulation Vol. 11 Forschungszentrum Julich, 2021, ISBN 978-3-95806-529-1 ¨ http://www.cond-mat.de/events/correl21
. . . .
. . . .
. . . .
. . . .
. . . .
. . . .
. . . .
. . . .
. . . .
. . . .
. . . .
. . . .
. . . .
. . . .
. . . .
. . . .
. . . .
. . . .
. . . .
. . . .
. . . .
. . . .
. . . .
. . . .
. . . .
. . . .
. . . .
. . . .
. . . .
. . . .
. . . .
. . . .
. . . .
. . . .
. . . .
. . . .
. . . .
. . . .
. . . .
. . . .
. . . .
. . . .
. . . .
. . . .
. . . .
. . . .
. . . .
. . . .
. . . .
. . . .
. . . .
. . . .
. . . .
. . . .
. . . .
24 24 25 26 28
1.2
1
Erik Koch
Many-electron states
One of the great mysteries of quantum mechanics is the existence of indistinguishable objects. Classically this is not possible: objects can always be distinguished, at least by their position in space, meaning that indistinguishable objects must be identical. This is Leibniz’ Principle of the Identity of Indiscernibles [1]. For quantum objects, however, the uncertainty principle makes the distinction of particles by their position impossible. This allows for the existence of elementary particles. They form the basic units of all matter. So, quite remarkably, all the different objects we know are made of indistinguishable building blocks. In the formalism of quantum mechanics, indistinguishability means that no observable lets us distinguish one of these particles from the other. Consequently, every observable for, e.g., electrons, must treat each electron in the same way. Thus, in principle, observables must act on all the electrons in the universe. In practice we can, of course, distinguish electrons localized on the moon from those in our lab to an excellent approximation. Thus, for all practical purposes, we can restrict ourselves to the electrons in the system under consideration, assuming that the differential overlap with all other electrons vanishes. Any observable M (x1 , . . . , xN ) for the N electrons in our system must then be symmetric under permutations of the coordinates xi . The consequences are straightforward: An observable M (x) acting on a single-particle degree P of freedom x must act on all indistinguishable particles in the same way, i.e., i M (xi ). LikeP wise, a two-body observable M (x, x0 ) must act on all pairs in the same way, i,j M (xi , xj ) with M (x, x0 ) = M (x0 , x). We can thus write any observable in the form 1 X 1 X (2) M (xi , xj ) + M (3) (xi , xj , xk ) + · · · (1) 2! 3! i i6=j i6=j6=k X X X (0) (1) (2) =M + M (xi ) + M (xi , xj ) + M (3) (xi , xj , xk ) + · · · , (2)
M (x) = M (0) +
X
i
M (1) (xi ) +
i