mesoscopic physics
\text{{mesoscopic physics}}
Mesoscopic physics and quantum transport (Phys672)
\text{Mesoscopic physics and quantum transport (Phys672)}
Computational Quantum Transport in Mesoscopic Systems (Phys673)
\text{Computational Quantum Transport in Mesoscopic Systems (Phys673) }
Course I:
\text{Course I:}
Course II:
\text{Course II:}
Hψ(xi)=2m∗a2ℏ2[2ψ(xi)−ψ(xi−a)−ψ(xi+a)]=Eψ(xi)
H \psi\left(x_i\right)=\frac{\hbar^2}{2 m^* a^2}\left[2 \psi\left(x_i\right)-\psi\left(x_i-a\right)-\psi\left(x_i+a\right)\right]=E \psi\left(x_i\right)
t = 1 r = 15 def circle(pos): x, y = pos return x**2 + y**2 < r**2 sys = kwant.Builder() sys[lat.shape(circle, (0,0))] = 4 * t sys[lat.neighbors()] = -t
Course I:
\text{Course I:}
Course Type:
\text { Course Type: }
Elective
\text{ Elective}
Level at which this course is offered:
\text{Level at which this course is offered: }
MS, Ph.D
\text{MS, Ph.D}
Pre-requisites for this course (if any):
\text{Pre-requisites for this course (if any):}
Graduate Standing
\text{ Graduate Standing}
Course Credit Hours:
\text{Course Credit Hours: }
3−0−3
3-0-3
Mesoscopic physics and quantum transport (Phys672)
\text{Mesoscopic physics and quantum transport (Phys672)}
Introduction to mesoscopic physics, Length scales, Confined geometries, Energy dependent density,band theory, Transport regime and review of conduction Phase-coherent transport, Ballistic transport, Landauer Buttiker formalism, conductance quantization, graphene related 2D materials, quantum Hall regime,spin-orbit coupling, Mesoscopic superconductivity
\text{Introduction to mesoscopic physics, Length scales, Confined geometries, Energy dependent density,}\\
\text{band theory, Transport regime and review of conduction Phase-coherent transport, Ballistic transport}\\
\text{, Landauer Buttiker formalism, conductance quantization, graphene related 2D materials, quantum Hall regime,}\\
\text{spin-orbit coupling, Mesoscopic superconductivity}
Course description
\text{Course description}
Course I:
\text{Course I:}
Mesoscopic physics and quantum transport (Phys672)
\text{Mesoscopic physics and quantum transport (Phys672)}
Course I:
\text{Course I:}
suggested book
\text{suggested book}
Mesoscopic physics and quantum transport (Phys672)
\text{Mesoscopic physics and quantum transport (Phys672)}
Thomas Henzel 2008
\text{Thomas Henzel 2008}
Yoseph Imry 2008
\text{Yoseph Imry 2008}
Gilles Mantambaux
\text{Gilles Mantambaux}
Course I:
\text{Course I:}
Benchmark
\text{Benchmark}
- Lecture: 2 Hour(s) per week x 14 weeks
\text{- Lecture: 2 Hour(s) per week x 14 weeks}
- Exercises: 2 Hour(s) per week x 14 weeks
\text{- Exercises: 2 Hour(s) per week x 14 weeks}
- Lectures+Exercises: 150 Hour(s) 12 weeks
\text{- Lectures+Exercises: 150 Hour(s) 12 weeks}
Mesoscopic physics and quantum transport (Phys672)
\text{Mesoscopic physics and quantum transport (Phys672)}
Ecole Polytechnique
\text{Ecole Polytechnique}
Grades distribution
\text{Grades distribution}
Assessment activities
\text{Assessment activities}
Course II:
\text{Course II:}
Computational Quantum Transport in Mesoscopic Systems (Phys673)
\text{Computational Quantum Transport in Mesoscopic Systems (Phys673) }
Course Type:
\text { Course Type: }
Elective
\text{ Elective}
Level at which this course is offered:
\text{Level at which this course is offered: }
MS, Ph.D
\text{MS, Ph.D}
Pre-requisites for this course (if any):
\text{Pre-requisites for this course (if any):}
Graduate Standing+
\text{ Graduate Standing+}
Course Credit Hours:
\text{Course Credit Hours: }
3−0−3
3-0-3
Phys 672 (Mesoscopic Physics and Quantum Transport)
\text{Phys 672 (Mesoscopic Physics and Quantum Transport)}
Course II:
\text{Course II:}
Computational Quantum Transport in Mesoscopic Systems (Phys673)
\text{Computational Quantum Transport in Mesoscopic Systems (Phys673) }
suggested book
\text{suggested book}
Documentation
\text{Documentation}
Course II:
\text{Course II:}
Computational Quantum Transport in Mesoscopic Systems (Phys673)
\text{Computational Quantum Transport in Mesoscopic Systems (Phys673) }
Course II:
\text{Course II:}
Computational Quantum Transport in Mesoscopic Systems (Phys673)
\text{Computational Quantum Transport in Mesoscopic Systems (Phys673) }
Benchmark
\text{Benchmark}
University of Delaware
\text{University of Delaware}
Mini-courses:
\text{Mini-courses:}
National Taiwan University
\text{National Taiwan University}
University of Belgrad
\text{University of Belgrad}
Course II:
\text{Course II:}
Computational Quantum Transport in Mesoscopic Systems (Phys673)
\text{Computational Quantum Transport in Mesoscopic Systems (Phys673) }
* Andreev reflections
\text{* Andreev reflections}
* Quantum point contact
\text{* Quantum point contact}
m e s o s c o p i c p h y s i c s \text{{mesoscopic physics}}
Mesoscopic phsics
By smstry
Mesoscopic phsics
- 108
