Baruch Feldman scite author profile

We present a real-space method for first-principles nano-scale electronic transport calculations. We use the non-equilibrium Green's function method with density functional theory and implement absorbing boundary conditions (ABCs, also known as complex absorbing potentials, or CAPs) to represent the effects of the semi-infinite leads. In real space, the Kohn-Sham Hamiltonian matrix is highly sparse. As a result, the transport problem parallelizes naturally and can scale favorably with system size, enabling the computation of conductance in relatively large molecular junction models. Our use of ABCs circumvents the demanding task of explicitly calculating the leads' self-energies from surface Green's functions, and is expected to be more accurate than the use of the jellium approximation. In addition, we take advantage of the sparsity in real space to solve efficiently for the Green's function over the entire energy range relevant to low-bias transport. We illustrate the advantages of our method with calculations on several challenging test systems and find good agreement with reference calculation results.

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Simulation of junctionless Si nanowire transistors with 3 nm gate length

Ansari

Feldman

Fagas

et al. 2010

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Simulation of grain boundary effects on electronic transport in metals, and detailed causes of scattering

Feldman

Park

Haverty

et al. 2010

phys. stat. sol. (b)

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Baruch Feldman

Real-space method for highly parallelizable electronic transport calculations

Simulation of junctionless Si nanowire transistors with 3 nm gate length

Simulation of grain boundary effects on electronic transport in metals, and detailed causes of scattering

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