Theory of Tunneling Spectroscopy in a Mn12 Single-Electron Transistor by Density-Functional Theory Methods

Lukasz Michalak; Carlo Canali; Mark R. Pederson; Magnus Paulsson; Vincenzo G. Benza

doi:10.1103/PhysRevLett.104.017202

Theory of Tunneling Spectroscopy in a Mn12 Single-Electron Transistor by Density-Functional Theory Methods

Lukasz Michalak, Carlo Canali, Mark R. Pederson, Magnus Paulsson, Vincenzo G. Benza

Research output: Contribution to journal › Article › peer-review

Abstract

We consider tunneling transport through a Mn12 molecular magnet using spin density functional theory. A tractable methodology for constructing many-body wave functions from Kohn-Sham orbitals allows for the determination of spin-dependent matrix elements for use in transport calculations. The tunneling conductance at finite bias is characterized by peaks representing transitions between spin multiplets, separated by an energy on the order of the magnetic anisotropy. The energy splitting of the spin multiplets and the spatial part of their many-body wave functions, describing the orbital degrees of freedom of the excess charge, strongly affect the electronic transport, and can lead to negative differential conductance.

Original language	English
Article number	017202
Number of pages	4
Journal	Physical Review Letters
Volume	104
Issue number	1
DOIs	https://doi.org/10.1103/PhysRevLett.104.017202
Publication status	Published - 2010 Jan 5
Externally published	Yes

Subject classification (UKÄ)

Condensed Matter Physics (including Material Physics, Nano Physics)

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10.1103/PhysRevLett.104.017202

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title = "Theory of Tunneling Spectroscopy in a Mn12 Single-Electron Transistor by Density-Functional Theory Methods",

abstract = "We consider tunneling transport through a Mn12 molecular magnet using spin density functional theory. A tractable methodology for constructing many-body wave functions from Kohn-Sham orbitals allows for the determination of spin-dependent matrix elements for use in transport calculations. The tunneling conductance at finite bias is characterized by peaks representing transitions between spin multiplets, separated by an energy on the order of the magnetic anisotropy. The energy splitting of the spin multiplets and the spatial part of their many-body wave functions, describing the orbital degrees of freedom of the excess charge, strongly affect the electronic transport, and can lead to negative differential conductance.",

author = "Lukasz Michalak and Carlo Canali and Pederson, {Mark R.} and Magnus Paulsson and Benza, {Vincenzo G.}",

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T1 - Theory of Tunneling Spectroscopy in a Mn12 Single-Electron Transistor by Density-Functional Theory Methods

AU - Michalak, Lukasz

AU - Canali, Carlo

AU - Pederson, Mark R.

AU - Paulsson, Magnus

AU - Benza, Vincenzo G.

PY - 2010/1/5

Y1 - 2010/1/5

N2 - We consider tunneling transport through a Mn12 molecular magnet using spin density functional theory. A tractable methodology for constructing many-body wave functions from Kohn-Sham orbitals allows for the determination of spin-dependent matrix elements for use in transport calculations. The tunneling conductance at finite bias is characterized by peaks representing transitions between spin multiplets, separated by an energy on the order of the magnetic anisotropy. The energy splitting of the spin multiplets and the spatial part of their many-body wave functions, describing the orbital degrees of freedom of the excess charge, strongly affect the electronic transport, and can lead to negative differential conductance.

AB - We consider tunneling transport through a Mn12 molecular magnet using spin density functional theory. A tractable methodology for constructing many-body wave functions from Kohn-Sham orbitals allows for the determination of spin-dependent matrix elements for use in transport calculations. The tunneling conductance at finite bias is characterized by peaks representing transitions between spin multiplets, separated by an energy on the order of the magnetic anisotropy. The energy splitting of the spin multiplets and the spatial part of their many-body wave functions, describing the orbital degrees of freedom of the excess charge, strongly affect the electronic transport, and can lead to negative differential conductance.

UR - https://arxiv.org/abs/0812.1058

U2 - 10.1103/PhysRevLett.104.017202

DO - 10.1103/PhysRevLett.104.017202

M3 - Article

SN - 1079-7114

VL - 104

JO - Physical Review Letters

JF - Physical Review Letters

IS - 1

M1 - 017202

ER -

Theory of Tunneling Spectroscopy in a Mn12 Single-Electron Transistor by Density-Functional Theory Methods

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