Atomistic theory of transport in organic and inorganic nanostructures

Pecchia, Alessandro; Carlo, Aldo Di

doi:10.1088/0034-4885/67/8/r04

Cited by 293 publications

(247 citation statements)

References 351 publications

(386 reference statements)

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“…The current and power are then computed as integrals over this energy grid. 9,12,13 These difficulties can be overcome if ͑i͒ the electronphonon coupling is weak, i.e., the probability for multiphonon processes is low, and ͑ii͒ the density of states ͑DOS͒ of the contacts and the device are slowly varying over a few phonon-energies around the Fermi energy E F , i.e., in the notation used below, G r ͑E͒ϷG r ͑E F ͒ and ⌫ 1,2 ͑E͒Ϸ⌫ 1,2 ͑E F ͒. These approximations are valid for systems where ͑i͒ the electron spends a short time compared to the phonon scattering time in the device and ͑ii͒ the closest resonance energy ͑E res ͒ is either far away from the Fermi energy ͉͑E res − E F ͉ ӷ⌫, eV, and ប ͒ or the broadening by the contacts is large ͑⌫ӷeV, ប , and ͉E res − E F ͉͒.…”

Section: ͑2͒mentioning

confidence: 99%

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Modeling inelastic phonon scattering in atomic- and molecular-wire junctions

2005

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Computationally inexpensive approximations describing electron-phonon scattering in molecularscale conductors are derived from the non-equilibrium Green's function method. The accuracy is demonstrated with a first principles calculation on an atomic gold wire. Quantitative agreement between the full non-equilibrium Green's function calculation and the newly derived expressions is obtained while simplifying the computational burden by several orders of magnitude. In addition, analytical models provide intuitive understanding of the conductance including non-equilibrium heating and provide a convenient way of parameterizing the physics. This is exemplified by fitting the expressions to the experimentally observed conductances through both an atomic gold wire and a hydrogen molecule.

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Section: ͑2͒mentioning

confidence: 99%

“…11 Phonon scattering is included in the SCBA method as self-energies to the electronic description. We use the undamped phonon Green's functions to express these selfenergies in the device subspace as 12,13,19 ⌺ ph…”

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confidence: 99%

Modeling inelastic phonon scattering in atomic- and molecular-wire junctions

2005

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“…They depend on the nonequilibrium density matrix ρ, which must be calculated self-consistently for each voltage V using cumbersome and computationally very demanding NEGF techniques. 5,[7][8][9][10][11][12] We propose here that in many situations ρ and its derived H M [ρ] need only be computed at zero voltage, and that the effect of a finite bias can be accounted for by the alignment or dealignment of the molecular orbitals at the extended molecule region with the energy levels of the electrodes (which are shifted by ±e V /2 by the bias voltage). Mathematically, we apply a simple shift to the Hamiltonian matrix elements from H M to H M + eV i S M , where the local shifts V i depend on the junction nature.…”

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confidence: 99%

“…1,2 However, the consistent and thorough work of a range of experimental groups has allowed researchers to reach some consensus on the conductance values and variability of a few specific junctions. [3][4][5] In addition, the development of simulation codes based on a combination of density functional theory (DFT) and the nonequilibrium Green's function formalism (NEGF) [5][6][7][8][9][10][11][12] has enabled theoreticians to assist the above experiments with theoretical insights and predictions. However, the size and complexity of the experimentally active part of the junction is typically too large, and the above codes need to assume a number of simplifications regarding the size, geometry, number of feasible atomic arrangements, and the electronic correlations.…”

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confidence: 99%

Nonequilibrium transport response from equilibrium transport theory

García‐Suárez

Ferrer

2012

Phys. Rev. B

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We propose a simple scheme that describes accurately essential nonequilibrium effects in nanoscale electronics devices using equilibrium transport theory. The scheme, which is based on the alignment and dealignment of the junction molecular orbitals with the shifted Fermi levels of the electrodes, simplifies drastically the calculation of current-voltage characteristics compared to typical nonequilibrium algorithms. We probe that the scheme captures a number of nontrivial transport phenomena such as the negative differential resistance and rectification effects. It applies to those atomic-scale junctions whose relevant states for transport are spatially placed on the contact atoms or near the electrodes. Nanoscale devices tend to suffer from a serious lack of reproducibility from one research group to another, and from a lack of durability and robustness. 1,2 However, the consistent and thorough work of a range of experimental groups has allowed researchers to reach some consensus on the conductance values and variability of a few specific junctions. [3][4][5] In addition, the development of simulation codes based on a combination of density functional theory (DFT) and the nonequilibrium Green's function formalism (NEGF) [5][6][7][8][9][10][11][12] has enabled theoreticians to assist the above experiments with theoretical insights and predictions. However, the size and complexity of the experimentally active part of the junction is typically too large, and the above codes need to assume a number of simplifications regarding the size, geometry, number of feasible atomic arrangements, and the electronic correlations. Recently, some of the above codes have been combined with classical force field programs, enabling the simulation of much larger systems and the sampling of a much wider set of atomic arrangements. 13,14 Nevertheless, present current-voltage I -V characteristics are still computed using NEGF techniques, which are rather cumbersome and extremely computer hungry. In other words, the NEGF is a serious bottleneck hindering the deployment of realistic transport simulations at the nanoscale. In contrast, equilibrium transport techniques are much simpler, better founded on physical grounds, and computationally drastically less demanding. 6 However, they are completely unable to reproduce current-voltage curves of nanoscale devices. 15 This is so because these techniques assume that the electronic states and the Hamiltonian at the junction do not change under the application of a voltage. However, a voltage bias drives a flow of electrons into and out of the junction, driving the device out of equilibrium and possibly even changing its quantum state and sometimes even its atomic arrangement. For example, the electric field originated by the voltage bias can also shift the energy position of the molecular levels by the Stark effect, depending on the polarizability of each molecular level or on whether the molecule has itself a polar nature. 16,17 We show here a suitable modification of equilibrium transport te...

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“…The nonequilibrium Green's function (NEGF) method [1,2] allows us to calculate quantum transport characteristics in ultra-small MOSFETs. By incorporating a tight-binding approximation (TBA) into the NEGF formalism one can achieve quantum-mechanical computations with atomic resolution [3]. We have reported on atomistic modeling for one-dimensional Si nanostructures within the framework of the NEGF formalism and an empirical TBA [4,5].…”

Section: Introductionmentioning

confidence: 99%

Crystalline Orientation Effects on Ballistic Hole Current in Ultrathin DG SOI MOSFETs

Minari

Mori

Simulation of Semiconductor Processes and Devices 2007

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Atomistic hole transport simulation based on a nonequilibrium Green's function method and a tight-binding approximation has been performed for two types of ultrathin doublegate silicon-on-insulator MOSFETs; (i) 100 -device on a {100} substrate where the current flows along the 100 direction and (ii) 110 -device on a {110} substrate where the current flow direction is the 110 direction. Simulation results show that the difference in crystalline orientation of the devices greatly affects ballistic hole current due to a strong confinement-induced mixing of heavy-and light-hole states.

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Atomistic theory of transport in organic and inorganic nanostructures

Cited by 293 publications

References 351 publications

Modeling inelastic phonon scattering in atomic- and molecular-wire junctions

Modeling inelastic phonon scattering in atomic- and molecular-wire junctions

Nonequilibrium transport response from equilibrium transport theory

Crystalline Orientation Effects on Ballistic Hole Current in Ultrathin DG SOI MOSFETs

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