Excited States with Selected Configuration Interaction-Quantum Monte Carlo: Chemically Accurate Excitation Energies and Geometries

Dash, Monika; Feldt, Jonas; Moroni, Saverio; Scemama, Anthony; Filippi, Claudia

doi:10.1021/acs.jctc.9b00476

Cited by 57 publications

(100 citation statements)

References 74 publications

Supporting

Mentioning

Contrasting

Unclassified

Order By: Relevance

“…Although among the employed trial wave functions, both of the SOCI‐J and SOCI‐J‐BF wave functions have computed the most accurate energies for the studied systems with similar accuracy. This characteristic feature is not seen in the other wave functions in the present or previous works. Despite very large computational cost, this method could provide efficient trial wave functions for different systems and states.…”

Section: Resultscontrasting

confidence: 76%

“…The previous studies through using the single‐ and multideterminant trial wave functions show that the QMC methods could provide an accurate description for both the ground and excited state properties . However, these studies have revealed that there is a strong dependence between the accuracy of the obtained energies and the quality of the trial wave function in the ground and excited states.…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Quantum Monte Carlo study of ground and first excited state of C, N, O, F, and Ne atoms using Slater‐Jastrow‐Backflow wave function

Nasiri

Zahedi

2020

Int J of Quantum Chemistry

View full text Add to dashboard Cite

All-electron fixed-node diffusion quantum Monte Carlo energies of the two lowestlying states of C, N, O, F, and Ne atoms are reported. The Slater-Jastrow form is used as the trial wave function. We will use single-and multideterminant wave functions as the Slater part. The single-determinant wave function has been computed by the Hartree-Fock method and the multideterminant wave functions have been computed by the complete active space self-consistent field, configuration interaction with single and double excitation, configuration interaction with single, double, triple, and quadruple excitation and second-order configuration interaction. For the groundand first excited states, the multideterminant wave functions have computed more than 99% of the correlation energy. Significant improvements have been achieved using the backflow transformations and up to 99.8% of the correlation energy has been recovered. A very good agreement with the experimental data has been obtained for the excitation energies. K E Y W O R D S backflow transformation, excited state, ground state of C, N, O an F atoms, quantum montecarlo, Slater-Jastrow

show abstract

Section: Resultscontrasting

confidence: 76%

Section: Introductionmentioning

confidence: 99%

Quantum Monte Carlo study of ground and first excited state of C, N, O, F, and Ne atoms using Slater‐Jastrow‐Backflow wave function

Nasiri

Zahedi

2020

Int J of Quantum Chemistry

View full text Add to dashboard Cite

show abstract

“…Using expansions with matched PT2 corrections has recently been shown to lead to accurate QMC excitation energies also for a relatively small number of determinants. 9 (ii) We perform the expansion of the two states simultaneously, using a common set of orbitals [the excited-state CASSCF(6,10) orbitals] and obtain automatically matched PT2 energy corrections during the expansion. 9 For the retinal model where the ground and excited states have the same symmetry, we have only one set of orbitals for the CIPSI expansions.…”

Section: Computational Detailsmentioning

confidence: 99%

“… 10 − 12 Importantly, recent methodological advancements 13 − 16 have enabled the fast calculation of energy derivatives and the optimization of many thousands of parameters for the internally consistent computation of QMC wave functions and geometries in the ground and excited states. 9 , 17 …”

Section: Introductionmentioning

confidence: 99%

Variational Principles in Quantum Monte Carlo: The Troubled Story of Variance Minimization

Cuzzocrea

Scemama

Briels

et al. 2020

J. Chem. Theory Comput.

Self Cite

124

View full text Add to dashboard Cite

We investigate the use of different variational principles in quantum Monte Carlo, namely, energy and variance minimization, prompted by the interest in the robust and accurate estimation of electronic excited states. For two prototypical, challenging molecules, we readily reach the accuracy of the best available reference excitation energies using energy minimization in a state-specific or state-average fashion for states of different or equal symmetry, respectively. On the other hand, in variance minimization, where the use of suitable functionals is expected to target specific states regardless of the symmetry, we encounter severe problems for a variety of wave functions: as the variance converges, the energy drifts away from that of the selected state. This unexpected behavior is sometimes observed even when the target is the ground state and generally prevents the robust estimation of total and excitation energies. We analyze this problem using a very simple wave function and infer that the optimization finds little or no barrier to escape from a local minimum or local plateau, eventually converging to a lower-variance state instead of the target state. For the increasingly complex systems becoming in reach of quantum Monte Carlo simulations, variance minimization with current functionals appears to be an impractical route.

show abstract

“…Es gibt auch noch andere Ansätze,d ie füra ngeregte Zustände eine Annäherung an FCI-Genauigkeit bieten. [69,70] Beispielsweise kçnnen angeregte Zustände mit verschiedenen Va rianten des stochastischen Quanten-Monte-Carlo-Verfahrens (QMC) [71,72] oder dessen Kombinationen mit anderen Te chniken [73,74] berechnet werden. Beispiele fürA nwendungen sind Azobenzol, [75] Festkçrper [76] oder Modelle fürd en Chromophor von Retinal.…”

Section: Multi-konfigurations-und Multi-referenz-methodenunclassified

Molekulare Photochemie: Moderne Entwicklungen in der theoretischen Chemie

Mai

González

2020

Angewandte Chemie

View full text Add to dashboard Cite

Photochemie ist ein faszinierendes Teilgebiet der Chemie, das sich mit der Wechselwirkung von Molekülen und Licht befasst. Die Simulation von lichtinduzierten Prozessen spielt auch in anderen Forschungsgebieten wie Biologie, Materialwissenschaften oder Medizin eine bedeutende Rolle. Dieser Kurzaufsatz beleuchtet die jüngsten Entwicklungen in der theoretischen Chemie, die das Ziel haben, experimentelle Genauigkeit bei der Berechnung von elektronisch angeregten Zuständen von Molekülen und bei der Simulation von deren lichtinduzierten Dynamiken zu erreichen. Wir konzentrieren uns dabei auf neue, aufstrebende Methoden und zeigen ausgewählte Beispiele, welche die Fortschritte der letzten Jahre für folgende Themen aufzeigen: die Voraussage komplexer Elektronenstrukturen mit starker Korrelation, die Berechnung von großen Molekülen, die Beschreibung von multi‐chromophorischen Systemen und die Simulation nicht‐adiabatischer Moleküldynamik auf langen Zeitskalen; dies umfasst Moleküle sowohl in der Gasphase als auch in komplexer biologischer Umgebung.

show abstract

Excited States with Selected Configuration Interaction-Quantum Monte Carlo: Chemically Accurate Excitation Energies and Geometries

Cited by 57 publications

References 74 publications

Quantum Monte Carlo study of ground and first excited state of C, N, O, F, and Ne atoms using Slater‐Jastrow‐Backflow wave function

Quantum Monte Carlo study of ground and first excited state of C, N, O, F, and Ne atoms using Slater‐Jastrow‐Backflow wave function

Variational Principles in Quantum Monte Carlo: The Troubled Story of Variance Minimization

Molekulare Photochemie: Moderne Entwicklungen in der theoretischen Chemie

Contact Info

Product

Resources

About