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Electronic properties of graphene
01DNIKG
A.A. 2021/22
Course Language
Inglese
Degree programme(s)
Doctorate Research in Fisica - Torino
Course structure
| Teaching | Hours |
|---|---|
| Lezioni | 21 |
Lecturers
| Teacher | Status | SSD | h.Les | h.Ex | h.Lab | h.Tut | Years teaching |
|---|---|---|---|---|---|---|---|
| Dolcini Fabrizio | Professore Ordinario | PHYS-04/A | 21 | 0 | 0 | 0 | 3 |
Co-lectures
Context
| SSD | CFU | Activities | Area context | *** N/A *** |
|---|
The discovery of graphene, a one-atom thick layer of carbon atoms forming a honeycomb lattice,
represents one of the most outstanding recent achievements in Physics, acknowledged in 2010
with the Nobel Prize awarded to A. Geim and K. Novoselov. Indeed this material exhibits fascinating
properties that make it unique for fundamental physics issues, and that have opened a new era in
nanoelectronics. On the one hand, electrons in graphene effectively behave as massless quantum
particles in the relativistic regime, opening up the possibility to observe relativistic effects in
condensed matter physics, such as the Klein tunneling or the unconventional quantum Hall effect.
On the other hand, graphene is characterized by a high carrier mobility and concentration, as well
as by extraordinary mechanical flexibility, which make it an ideal candidate as a platform for the
foldable electronics in the near future. The purpose of this course is to provide an overview of the
electronic properties of graphene, pointing out the peculiarities with respect to conventional
materials and their possible application impact. After an introductory part, I shall present the models
that are utilized to describe the electronic band structure and the electron transport in bulk
graphene and in nanoribbons. The second part of the course will be devoted to more specific topics
(depending also on the students’ interest), such as the mesoscopic effects, the optical response,
the hybrid junctions graphene-superconductors, and the arise of topological edge states in
graphene.
The discovery of graphene, a one-atom thick layer of carbon atoms forming a honeycomb lattice,
represents one of the most outstanding recent achievements in Physics, acknowledged in 2010
with the Nobel Prize awarded to A. Geim and K. Novoselov. Indeed this material exhibits fascinating
properties that make it unique for fundamental physics issues, and that have opened a new era in
nanoelectronics. On the one hand, electrons in graphene effectively behave as massless quantum
particles in the relativistic regime, opening up the possibility to observe relativistic effects in
condensed matter physics, such as the Klein tunneling or the unconventional quantum Hall effect.
On the other hand, graphene is characterized by a high carrier mobility and concentration, as well
as by extraordinary mechanical flexibility, which make it an ideal candidate as a platform for the
foldable electronics in the near future. The purpose of this course is to provide an overview of the
electronic properties of graphene, pointing out the peculiarities with respect to conventional
materials and their possible application impact. After an introductory part, I shall present the models
that are utilized to describe the electronic band structure and the electron transport in bulk
graphene and in nanoribbons. The second part of the course will be devoted to more specific topics
(depending also on the students’ interest), such as the mesoscopic effects, the optical response,
the hybrid junctions graphene-superconductors, and the arise of topological edge states in
graphene.
Basic physics knowledge and linear algebra are mandatory prerequisites. Some basic knowledge of Solid state Physics and Quantum Mechanics is helpful, although not strictly needed (the first part will be devoted to a quick overview of the main concepts)
Basic physics knowledge and linear algebra are mandatory prerequisites. Some basic knowledge of Solid state Physics and Quantum Mechanics is helpful, although not strictly needed (the first part will be devoted to a quick overview of the main concepts)
-Introduction to carbon-based materials
-Graphene: overview and general properties
-A short survey of electronic properties in solids
-The electronic band structure of graphene: from the tight-binding model to the Dirac equation for massless electrons
-Relativistic effects in condensed matter: Klein paradox and unconventional Quantum Hall effect
-Graphene n-p junctions: Electron focussing and Veselago lenses
-Graphene bilayers and tunable band gap
-Mesoscopic effects in graphene
-Introduction to carbon-based materials
-Graphene: overview and general properties
-A short survey of electronic properties in solids
-The electronic band structure of graphene: from the tight-binding model to the Dirac equation for massless electrons
-Relativistic effects in condensed matter: Klein paradox and unconventional Quantum Hall effect
-Graphene n-p junctions: Electron focussing and Veselago lenses
-Graphene bilayers and tunable band gap
-Mesoscopic effects in graphene
In presenza
On site
Presentazione orale
Oral presentation
P.D.1-1 - Febbraio
P.D.1-1 - February
Lecture notes of the course will be available. The final test consists in an informal test, where the PhD student is expected to discuss at the blackboard the basic concepts of the topics of the course.