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Quantum MonteCarlo Simulation of Single Electron Tunneling Transistors'

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To simulate SETs and study I-V characteristics, Coulomb blockade, and Kondo ... Time-table. Year 1 Year 2 Year 3. Develop QMC algorithm for tight binding model ... – PowerPoint PPT presentation

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Title: Quantum MonteCarlo Simulation of Single Electron Tunneling Transistors'


1
Quantum Monte-Carlo Simulation of Single
Electron Tunneling Transistors.
  • B.Gelmont
  • University of Virginia

2
Single Electron Tunneling Transistor (SET)
  • Basic principles of operation.
  • Small size ( 10 nm-100 nm).
  • Tunneling contacts.
  • Coulomb blockade.
  • Threshold voltage.
  • Coulomb Staircase.
  • Unique transport properties of the SET.
  • Kondo effect.

3
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Vg2
6
Possible Applications.
  • Current control sources.
  • Supersensitive electrometry, dc current and
    resistance standards, temperature standard
  • Terahertz radiation detection.
  • Logic device with the presence or absence of a
    single electron .
  • The pump and turnstile devices as frequency
    controlled current sources.
  • Basic building blocks of quantum-dot cellular
    automata (QCA) or as memory elements.

7
Present understanding.
  • The perturbation theory in the limit of the small
    quantum resistance in comparison with the
    tunneling resistance.
  • The Renormalization Group analysis and instanton
    techniques in the limit of high tunneling
    conductance.
  • No general consensus about the dependence of the
    charging energy on the ratio of the quantum and
    tunneling resistances.

8
Quantum Monte-Carlo (QMC).
  • QMC requires mapping of quantum ensemble on
    classical system of higher dimension
    (Trotter-like formula of exponential operators).
  • The problem is how to develop QMC technique for
    fermions.
  • Two different ways to transform the path integral
    into a form suitable for the QMC simulation.

9
Objectives
  • To develop a QMC algorithm for tight binding
    model of electrons in semiconductor quantum dots.
  • To simulate SETs and study I-V characteristics,
    Coulomb blockade, and Kondo effects.
  • To develop QMC algorithm for free electrons in
    the metallic dots and to simulate SETs at
    different ratios of the quantum and the tunneling
    resistances.
  • To perform simulation of a line of QCA cells, to
    demonstrate the transmission of information from
    cell to cell.
  • QMC algorithm for random distances between sites.

10
Computer problem
  • QMC simulations generally demand large amounts of
    computational resources.
  • To realize the full potential of computer
    simulation, the computational bottlenecks must be
    overcome by employing parallel computing
    techniques.
  • We propose to develop a QMC simulator based on
    Message Passing Interface (MPI) parallel
    computing technique.

11
Time-table
  • Year 1 Year 2 Year 3

Develop QMC algorithm for tight binding
model Simulation of SETs Develop QMC algorithm
for the metallic dot
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