Professor Ali Alavi FRS

Professor of Theoretical Chemistry

The work of our group is primarily focused on the electron correlation problem - namely how to compute the correlation energy for an atom, molecule, or even solid, starting from a mean-field (say Hartree-Fock) description of the system. Our approach is to combine quantum chemical ideas with stochastic (Monte Carlo) techniques, which enable us to tackle problems which are very difficult to solve use standard quantum chemical techniques alone.

We are developing Quantum Monte Carlo algorithms adapted for electronic (and more generally Fermionic) problems by working in Slater determinant spaces. The central problem which is encountered is the infamous "Fermion sign problem", which results from electronic wavefunctions having both positive and negative amplitudes. Currently we are working on a novel population dynamics algorithm which propagates walkers in Slater determinant space according to a type of "stochastic cellular automaton" obeying simple rules. The movie on the home page of our research group website shows an evolving population of walkers of positive and negative sign settling on the FCI wavefunction of a nitrogen dimer in a minimal basis - an archetypal multireference system. The remarkable aspect of this dynamics is the spontaneous symmetry breaking caused by annhilation processes, allowing the exact nodal surface of the nitrogen molecule, as expressed by the CI coefficients, molecule to appear. No fixed-node approximation is applied.

Further animations of this method in action can be viewed here.

Publications

Combining the Complete Active Space Self-Consistent Field Method and the Full Configuration Interaction Quantum Monte Carlo within a Super-CI Framework, with Application to Challenging Metal-Porphyrins.

G Li Manni, SD Smart, A Alavi

– J Chem Theory Comput

(2016)

12,

1245

(doi: 10.1021/acs.jctc.5b01190)

Quasi-degenerate perturbation theory using matrix product states

S Sharma, G Jeanmairet, A Alavi

– Journal of Chemical Physics

(2016)

144,

034103

(doi: 10.1063/1.4939752)

Stochastic quantum chemistry for strong correlation

G Booth, R Thomas, N Blunt, R Anderson, Q Sun, T Shiozaki, A Alavi

– ABSTRACTS OF PAPERS OF THE AMERICAN CHEMICAL SOCIETY

(2016)

251,

(link to publication)

Stochastic Multiconfigurational Self-Consistent Field Theory

RE Thomas, Q Sun, A Alavi, GH Booth

– J Chem Theory Comput

(2015)

11,

5316

(doi: 10.1021/acs.jctc.5b00917)

An excited-state approach within full configuration interaction quantum Monte Carlo.

NS Blunt, SD Smart, GH Booth, A Alavi

– The Journal of chemical physics

(2015)

143,

134117

(doi: 10.1063/1.4932595)

Preface: Special Topic Section on Advanced Electronic Structure Methods for Solids and Surfaces.

A Michaelides, TJ Martinez, A Alavi, G Kresse, FR Manby

– J Chem Phys

(2015)

143,

102601

(doi: 10.1063/1.4930182)

Multireference linearized coupled cluster theory for strongly correlated systems using matrix product states

S Sharma, A Alavi

– The Journal of chemical physics

(2015)

143,

102815

(doi: 10.1063/1.4928643)

Analytic nuclear forces and molecular properties from full configuration interaction quantum Monte Carlo

RE Thomas, D Opalka, C Overy, PJ Knowles, A Alavi, GH Booth

– Journal of Chemical Physics

(2015)

143,

054108

(doi: 10.1063/1.4927594)

Krylov-Projected Quantum Monte Carlo Method

NS Blunt, A Alavi, GH Booth

– Physical Review Letters

(2015)

115,

050603

(doi: 10.1103/physrevlett.115.050603)

Semi-stochastic full configuration interaction quantum Monte Carlo: Developments and application.

NS Blunt, SD Smart, JAF Kersten, JS Spencer, GH Booth, A Alavi

– J Chem Phys

(2015)

142,

184107

(doi: 10.1063/1.4920975)

Professor of Theoretical Chemistry

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