Electrode-molecule energy level offsets in a gold-benzene diamine-gold single molecule tunnel junction

Szepieniec, Mark; Greer, James C.

doi:10.1063/5.0024567

Cited by 3 publications

(2 citation statements)

References 45 publications

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“…Our approach is similar in spirit to the many-electron correlated scattering (MECS) formalism which constructs the 1-RDM from a full CI wave function through a constrained minimization and, hence, affords a many-body picture of electron transport. The latter formalism has been shown to be extremely successful on a variety of systems in the past , and has recently even been demonstrated to attain excellent agreement with experiment and with the self-interaction error corrected version of DFT-NEGF by Quek et al Unlike the MECS formalism, our method variationally obtains the 1-RDM directly from a constrained semidefinite optimization scheme on the two-particle reduced density matrix (2-RDM).…”

Section: Theory/methodsmentioning

confidence: 99%

Conductance Switching in an Organometallic Single-Electron Transistor Using Current-Constrained Reduced-Density Matrix Theory

2021

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We report switching of molecular conductance at finite bias in a binuclear organometallic complex and its cation which were previously experimentally analyzed at low voltages to see the signature of Kondo resonance. The variational reduced density matrix theory is applied to show that the system is strongly multireferenced especially in its charged form. We also study the molecular conductance of both forms using recently developed current-constrained two-electron reduced density matrix theory which is capable of handling strong electronic correlation. We compare the results against an uncorrelated 1-electron reduced density matrix version of conductance calculations using Hartree−Fock molecular orbitals. We observe that despite quantitative disagreements, the qualitative trend in the conductance is correctly predicted to be favorable for the cationic partner by both methods. We explain the results using the inherently high density of states for the low-lying excited states in the cationic partner which is also replicable from uncorrelated electronic structure methods. Our results not only indicate that the low-bias conductance trend is maintained even beyond the Kondo regime and produces quantitative agreement with that of the experiment but also identifies important physical markers that are responsible for the high conductance of the charged species.

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Section: Theory/methodsmentioning

confidence: 99%

Conductance Switching in an Organometallic Single-Electron Transistor Using Current-Constrained Reduced-Density Matrix Theory

2021

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“…22 To the authors' knowledge, none are yet in widespread use even though interest in other multireference transport methods such as multilayer multiconfiguration time-dependent Hartree method, time-dependent reduced density matrix theories, and time-dependent CI theories is growing rapidly. 9,[23][24][25][26][27][28][29] This is likely due, at least in part, to the computational cost of using a CI wavefunction to construct the Green's function directly. This cost can be mitigated if an active space approach is employed, such as the complete active space self-consistent field (CASSCF) method.…”

Section: Introductionmentioning

confidence: 99%

A multiconfigurational pair-density functional theory approach to molecular junctions

Sand,

Malme,

Hoy

2021

Preprint

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Due to their small size and unique properties, single-molecule electronics have long seen research interest from experimentalists and theoreticians alike. From a theoretical standpoint, modeling these systems using electronic structure theory can be difficult due to the importance of electron correlation in the determination of molecular properties, and this electron correlation can be computationally expensive to consider, particularly multiconfigurational correlation energy. In this work, we develop a new approach for the study of single-molecule electronic systems, denoted NEGF-MCPDFT, which combines multiconfiguration pair-density functional theory (MC-PDFT) with the non-equilibrium Green's function formalism (NEGF). The use of MC-PDFT with NEGF allows for the efficient inclusion of both static and dynamic electron correlation in the description of the junction's electronic structure. CASSCF wave functions are used as references in the MC-PDFT calculation, and like with any active space method, effort must be made to determine the proper orbital character to include in the active space. We perform conductance and transmission calculations on a series of alkanes (predominantly single-configurational character) and benzyne (multiconfigurational character), exploring the role that active space selection has on the computed

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A multiconfiguration pair-density functional theory-based approach to molecular junctions

Sand

Malme

Hoy

2021

The Journal of Chemical Physics

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Due to their small size and unique properties, single-molecule electronics have long seen research interest from experimentalists and theoreticians alike. From a theoretical standpoint, modeling these systems using electronic structure theory can be difficult due to the importance of electron correlation in the determination of molecular properties, and this electron correlation can be computationally expensive to consider, particularly multiconfigurational correlation energy. In this work, we develop a new approach for the study of single-molecule electronic systems, denoted NEGF-MCPDFT, which combines multiconfiguration pair-density functional theory (MCPDFT) with the non-equilibrium Green’s function formalism (NEGF). The use of MCPDFT with NEGF allows for the efficient inclusion of both static and dynamic electron correlations in the description of the junction’s electronic structure. Complete active space self-consistent field wave functions are used as references in the MCPDFT calculation, and as with any active space method, effort must be made to determine the proper orbital character to include in the active space. We perform conductance and transmission calculations on a series of alkanes (predominantly single-configurational character) and benzyne (multiconfigurational character), exploring the role that active space selection has on the computed results. For the alkane junctions explored (where dynamic electron correlation dominates), the MCPDFT-NEGF results agree well with the DFT-NEGF results. For the benzyne junction (which has a significant static correlation), we see clear differences in the MCPDFT-NEGF and DFT-NEGF results and evidence that NEGF-MCPDFT is capturing additional electron correlation effects beyond those provided by the Perdew–Burke–Ernzerhof functional.

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Electrode-molecule energy level offsets in a gold-benzene diamine-gold single molecule tunnel junction

Cited by 3 publications

References 45 publications

Conductance Switching in an Organometallic Single-Electron Transistor Using Current-Constrained Reduced-Density Matrix Theory

Conductance Switching in an Organometallic Single-Electron Transistor Using Current-Constrained Reduced-Density Matrix Theory

A multiconfigurational pair-density functional theory approach to molecular junctions

A multiconfiguration pair-density functional theory-based approach to molecular junctions

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