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! <h2 style="margin:0;background-color:#cef2e0;font-size:120%;font-weight:bold;border:1px solid #a3bfb1;text-align:left;color:#000;padding:0.2em 0.4em;"> Course Topics</h2>
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|style="color:#000"|[[Image:she_ishe.jpg|left|400px]] The course provides a hands-on experience for graduate students in sciences (physics, chemistry) and engineering (electrical, chemical, materials), as well as advanced undergraduates, to analyze electronic structure and transport properties of basic classes of  carbon, semiconductor, and magnetic nanostructures explored at the current research frontiers.
|style="color:#000"|[[Image:she_ishe.jpg|left|300px]] The course provides a hands-on experience for graduate students in sciences (physics, chemistry) and engineering (electrical, chemical, materials), as well as advanced undergraduates, to analyze electronic structure and transport properties of basic classes of  carbon, semiconductor, and magnetic nanostructures explored at the current research frontiers.
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|style="color:#000"|{{Course Topics}}
|style="color:#000"|{{Course Topics}}

Revision as of 19:53, 29 August 2016

UDcoaCweb.jpg
PHYS 824: Introduction to Nanophysics


The 12-hour version of the course was offered at the National Taiwan University in March 2010
The 15-hour version of the course was offered at the University of Belgrade, Serbia in June 2010
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Course Topics

She ishe.jpg
The course provides a hands-on experience for graduate students in sciences (physics, chemistry) and engineering (electrical, chemical, materials), as well as advanced undergraduates, to analyze electronic structure and transport properties of basic classes of carbon, semiconductor, and magnetic nanostructures explored at the current research frontiers.
  • Nanostructures in equilibrium: graphene and other two-dimensional materials, carbon nanotubes, topological insulators, magnetic multilayers.
  • Nanostructure out of equilibrium: conductance quantization, quantum interference, spin-dependent tunneling, spin and quantum Hall effects, spin-transfer torque, I-V curves.
  • Theoretical techniques: elements of density functional theory (DFT), Landauer-Büttiker scattering formalism, nonequilibrium Green function techniques.
  • Experimental techniques: scanning tunneling and atomic force microscopy.
  • Applications: nanoelectronics, spintronics, thermoelectrics.

News

  • Final Project is posted and due on Friday 12/16 as poster presentation in Sharp Lab 225 at 2:00PM.

Lecture in Progress

  • Application of Landauer-Büttiker formula to quantum interference effects in electronic transport

Quick Links

Course Motto

  • In teaching, writing, and research, there is no greater clarifier than a well-chosen example.
  • Formalism should not be introduced for its own sake, but only when it is needed for some particular problem.
  • Physics comes in two parts: the precise mathematical formulation of the laws, and the conceptual interpretation of the mathematics. However, if words of conceptual interpretation actually convey the wrong meaning of the mathematics, they must be replaced by more accurate words. (W. J. Mullin)

ACKNOWLEDGMENT: Portion of the course material is based upon work supported by the National Science Foundation under Grants No. ECCS 0725566 and ECCS 1202069. Any opinions, findings, and conclusions or recommendations expressed in this material are those of the author and do not necessarily reflect the views of the National Science Foundation.

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