Course Syllabus

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Un materiale quantistico è un materiale le cui proprietà elettroniche o magnetiche sono meglio descritte come originate da effetti quantomeccanici non banali, in altre parole materiali in cui particelle o calcoli semi-classici, che non considerano il carattere completo del sistema, non descrivono adeguatamente le proprietà elettroniche o magnetiche osservate.
Il corso presenta i principi fisici alla base delle proprietà dei materiali quantistici, consentendo così di comprendere questi materiali in dettaglio. Verranno trattati in dettaglio diversi sistemi di materiali: dai superconduttori, il prototipo di materiale quantistico, all'effetto hall quantistico intero e agli isolanti topologici, che mostrano una stretta connessione delle loro proprietà elettroniche con invarianti derivati dalla topologia.

Obiettivi
• Conoscenza dettagliata dei concetti e degli approcci di base nella ricerca sui materiali quantistici.
• Comprendere i fenomeni emergenti nei materiali quantistici
• Comprendere gli effetti della topologia e delle simmetrie sulle proprietà elettroniche quantistiche dei materiali
• Acquisizione di capacità comunicative verbali e scritte in concetti avanzati di fisica quantistica.

• Introduzione: Materiali quantistici per tecnologie quantistiche.
• Teoria dei Superconduttori di Ginzburg Landau
• Effetto Hall quantistico intero
• Topologia e fase Berry
• Invarianti topologici e proprietà fisiche

Introduzione:
• i materiali quantistici come strumento per le moderne tecnologie quantistiche.
• Panoramica dei prerequisiti del corso, dei contenuti delle lezioni, dei libri di testo/letteratura e dei metodi di valutazione.
Superconduttori
• Termodinamica: superconduttori di tipo I e II
• Elettrodinamica
• Interazione elettrone-fonone e coppie di Cooper
• Teoria di Ginzburg-Landau
• Effetto Josephson e CALAMARI
• Q-Bit quantistici superconduttori
• Effetto Hall quantistico intero
• Livelli Landau
• Teoria di Laughlin dell'effetto Hall quantistico
• Perché 2D, disordine e localizzazione sono importanti
• Teoria della percolazione semiclassica
• Stati del bordo IQHE
Topologia
• Fase di Berry, connessione e curvatura
• Fase di Berry per gli elettroni nei cristalli
• Applicazioni della fase di Berry: effetto Aharonov-Bohm, polarizzazione dei cristalli, elettroni cristallini in campo elettrico uniforme
• Numeri Chern
• Simmetrie di inversione temporale e di inversione: simmetria spezzata in Honeycomb Lattice
• IQHE senza livelli Landau
• Invarianti topologiche

Concetti di meccanica quantistica e fisica dello stato solido.

Lezioni frontali ed esercitazioni alla lavagna e/o slides.

Le diapositive saranno messe a disposizione degli studenti attraverso la presente piattaforma e-learning.

Testi

• P. G. De Gennes (1999) Superconductivity of Metals and Alloys, Westview Press, ISBN 0-7382-0101-4
• Efthimios Kaxiras & John D. Joannopoulos (2019) Quantum Theory of Materials, Cambridge University Press. doi 10.1017/9781139030809:
• Girvin, S., & Yang, K. (2019). Modern Condensed Matter Physics. Cambridge University Press. doi:10.1017/9781316480649
• B. I. Shklovskii & A. L. Efros (2013) Electronic Properties of Doped Semiconductors Springer. isbn:9783662024034
• Raffaele Resta, Geometry and Topology in Electronic Structure Theory, Notes, http://www-dft.ts.infn.it/~resta/gtse/draft.pdf
• Giuseppe Grosso & Giuseppe Pastori Parravicini (2013), Solid State Physics, Academic Press. isbn:9780123850317
• János K. Asbóth, László Oroszlány, András Pályi (2016). A Short Course on Topological Insulators: Band Structure and Edge States in One and Two Dimensions. Springer

Articoli scientifici
Diversi argomenti del corso sono anche ben presentati in articoli scientifici, come ad esempio:

  • Von Klitzing K (1986) The quantized Hall effect, Reviews of Modern Physics 58, 519
  • R. B. Laughlin (1981) Quantized Hall conductivity in two dimensions, Phys. Rev. B 23, 5632
  • Feliciano Giustino et al (2020) The 2021 quantum materials roadmap. J. Phys. Mater. 3 042006.
  • B. Keimer & J. E. Moore (2017) The physics of quantum materials. Nature Physics 13, 1045–1055.
  • Hasan MZ, Kane CL (2010) Colloquium: Topological insulators. Reviews of Modern Physics, 82(4):3045–3067.
  • Haldane FDM (1988) Model for a Quantum Hall Effect without Landau Levels: Condensed-Matter Realization of the "Parity Anomaly", Phys Rev. Lett. 61, 2015

secondo semetre

Le conoscenze degli studenti saranno valutate attraverso una prova orale incentrata sugli argomenti trattati durante il corso.

Dal lunedì al venerdì a qualsiasi ora lavorativa (previo appuntamento con il docente via email).

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A quantum material is one whose electronic or magnetic properties are best described as having a nontrivial quantum mechanical origin, in other words materials where classical particles or calculations that do not consider the full character of the system do not adequately describe the electronic or magnetic properties displayed.
The course presents the physical principles underlying the quantum materials properties, thus permitting to understand these materials from the basis. Several materials systems will be treated in detail: from superconductors, the prototypical example of a quantum material, to integer quantum hall effect and topological insulators, which show a strict connection of their electronic properties with topology derived invariants.

Learning Outcomes
• Detailed knowledge of the basic concepts and approaches in quantum materials research.
• Understanding emergent phenomena in quantum materials
• Understanding the effects of topology and symmetries on the quantum electronic properties of materials
• Acquisition of verbal and written communication skills in advanced concepts of quantum physics.

• Introduction: Quantum materials for quantum technologies.
• Ginzburg Landau theory of Superconductors
• Integer Quantum Hall Effect
• Topology and Berry phase
• Topological invariants and physical properties

Introduction:
• quantum materials as a tool for modern quantum technologies.
• Overview of course pre-requisite, lecture contents, textbooks/literature, and assessment methods.
Superconductors
• Thermodynamics: type I & II superconductors
• Electrodynamics
• Electron-phonon interaction & Cooper pairs
• Ginzburg-Landau Theory
• Josephson effect & SQUIDS
• Superconducting quantum bits
• Integer Quantum Hall Effect
• Landau Levels
• Laughlin theory of the Quantum Hall Effect
• Why 2D, disorder and localization are important
• Semiclassical percolation theory
• IQHE edge states
Topology
• Berry phase, Connection and curvature
• Berry’s Phase for Electrons in Crystals
• Applications of Berry’s Phase: Aharonov–Bohm Effect, Polarization of Crystals, Crystal Electrons in Uniform Electric Field
• Chern Numbers
• Time-reversal and inversion symmetries: Broken Symmetry in Honeycomb Lattice
• IQHE without Landau Levels
• Topological Invariants

Quantum mechanics and solid-state physics concepts.

Frontal lectures and exercise sessions using blackboard and/or slides.

Slides will be made available to the students through the present e-learning platform.
Textbooks:
• P. G. De Gennes (1999) Superconductivity of Metals and Alloys, Westview Press, ISBN 0-7382-0101-4
• Efthimios Kaxiras & John D. Joannopoulos (2019) Quantum Theory of Materials, Cambridge University Press. doi 10.1017/9781139030809:
• Girvin, S., & Yang, K. (2019). Modern Condensed Matter Physics. Cambridge University Press. doi:10.1017/9781316480649
• B. I. Shklovskii & A. L. Efros (2013) Electronic Properties of Doped Semiconductors Springer. isbn:9783662024034
• Raffaele Resta, Geometry and Topology in Electronic Structure Theory, Notes, http://www-dft.ts.infn.it/~resta/gtse/draft.pdf
• Giuseppe Grosso & Giuseppe Pastori Parravicini (2013), Solid State Physics, Academic Press. isbn:9780123850317
• János K. Asbóth, László Oroszlány, András Pályi (2016). A Short Course on Topological Insulators: Band Structure and Edge States in One and Two Dimensions. Springer

Scientific articles:
Different topics of the course are also well presented in scientific articles, such as:

  • Von Klitzing K (1986) The quantized Hall effect, Reviews of Modern Physics 58, 519
  • R. B. Laughlin (1981) Quantized Hall conductivity in two dimensions, Phys. Rev. B 23, 5632
  • Feliciano Giustino et al (2020) The 2021 quantum materials roadmap. J. Phys. Mater. 3 042006.
  • B. Keimer & J. E. Moore (2017) The physics of quantum materials. Nature Physics 13, 1045–1055.
  • Hasan MZ, Kane CL (2010) Colloquium: Topological insulators. Reviews of Modern Physics, 82(4):3045–3067.
  • Haldane FDM (1988) Model for a Quantum Hall Effect without Landau Levels: Condensed-Matter Realization of the "Parity Anomaly", Phys Rev. Lett. 61, 2015

second semester

Students’ knowledge will be evaluated through an oral exam focusing on the topics discussed during the course.

From Monday to Friday at any working hour (an appointment should be arranged with the teacher by email).

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Key information

Field of research
FIS/03
ECTS
6
Term
Second semester
Activity type
Mandatory to be chosen
Course Length (Hours)
42
Degree Course Type
2-year Master Degreee
Language
English

Staff

    Teacher

  • Stefano Sanguinetti
    Stefano Sanguinetti

Students' opinion

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Bibliography

Find the books for this course in the Library

Enrolment methods

Manual enrolments
Self enrolment (Student)

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