Suchergebnis: Katalogdaten im Herbstsemester 2023

Physik Master Information
Kernfächer
Ein experimentelles oder theoretisches Bachelorkernfach kann als Masterkernfach angerechnet werden, allerdings kann dieses nicht benutzt werden, um das obligatorische experimentelle oder theoretische Kernfach im Master zu kompensieren.
Für die Kategoriezuordnung lassen Sie bei der Prüfungsanmeldung "keine Kategorie" ausgewählt und wenden Sie sich nach dem Verfügen des Prüfungsresultates an das Studiensekretariat (www.phys.ethz.ch/de/studium/studiensekretariat.html).
Theoretische Kernfächer
NummerTitelTypECTSUmfangDozierende
402-0861-00LStatistical PhysicsW10 KP4V + 2UG. M. Graf
KurzbeschreibungThe lecture covers the concepts of classical and quantum statistical physics. The discussion ranges from foundations to specific systems, including their formalisms and techniques, such as bosonic and fermionic gases, and magnetism. Phenomena, most notably phase transitions, are treated by methods such as exact solutions, mean-field approximations, and the renormalization group.
LernzielThis lecture gives an introduction to the basic concepts and applications of statistical physics for general use in physics and, in particular, as preparation for theoretical solid-state physics.
InhaltThermodynamics: Laws of thermodynamics, thermodynamic potentials, phenomenology of phase transitions of first and second order. Van der Waals gas-liquid transition.
Classical statistical physics: micro-canonical-, canonical-, and grand canonical ensembles; the arrow of time, applications to interacting systems, and cumulant expansion.
Quantum statistical physics: density matrix, ensembles, ideal quantum gases, fermions and bosons, second quantization, statistical interaction.
Degenerate fermions: Fermi gas, electrons in magnetic field.
Bosons: photons and phonons, Bose-Einstein condensation. Bogolyubov’s theory of superfluidity and liquid Helium.
Magnetism: Ising-, XY-, Heisenberg models, exact solutions, mean-field theory, Peierls' argument on long-range order, Berezinskii-Kosterlitz-Thouless transition.
Landau theory of phase transitions and symmetry.
Critical phenomena: scaling theory, universality, and the renormalization group.
SkriptLecture notes available in English.
LiteraturNo specific book is used for the course. Relevant literature will be given in the course.
KompetenzenKompetenzen
Fachspezifische KompetenzenKonzepte und Theoriengeprüft
Methodenspezifische KompetenzenAnalytische Kompetenzengeprüft
Problemlösunggeprüft
402-0843-00LQuantum Field Theory I
Fachstudierende UZH müssen das Modul PHY551 direkt an der UZH buchen.
W10 KP4V + 2UC. Anastasiou
KurzbeschreibungThis course discusses the quantisation of fields in order to introduce a coherent formalism for the combination of quantum mechanics and special relativity.
Topics include:
- Relativistic quantum mechanics
- Quantisation of bosonic and fermionic fields
- Interactions in perturbation theory
- Scattering processes and decays
- Elementary processes in QED
- Radiative corrections
LernzielThe goal of this course is to provide a solid introduction to the formalism, the techniques, and important physical applications of quantum field theory. Furthermore it prepares students for the advanced course in quantum field theory (Quantum Field Theory II), and for work on research projects in theoretical physics, particle physics, and condensed-matter physics.
SkriptWill be provided as the course progresses
KompetenzenKompetenzen
Fachspezifische KompetenzenKonzepte und Theoriengeprüft
Verfahren und Technologiengeprüft
Methodenspezifische KompetenzenAnalytische Kompetenzengeprüft
Entscheidungsfindunggefördert
Medien und digitale Technologiengefördert
Problemlösunggeprüft
Projektmanagementgefördert
Soziale KompetenzenKommunikationgefördert
Kooperation und Teamarbeitgefördert
Kundenorientierunggefördert
Menschenführung und Verantwortunggefördert
Selbstdarstellung und soziale Einflussnahmegefördert
Sensibilität für Vielfalt gefördert
Verhandlunggefördert
Persönliche KompetenzenAnpassung und Flexibilitätgefördert
Kreatives Denkengeprüft
Kritisches Denkengeprüft
Integrität und Arbeitsethikgefördert
Selbstbewusstsein und Selbstreflexion gefördert
Selbststeuerung und Selbstmanagement gefördert
402-0830-00LGeneral Relativity Information W10 KP4V + 2UL. Senatore
KurzbeschreibungIntroduction to the theory of general relativity. The course puts a strong focus on the mathematical foundations of the theory as well as the underlying physical principles and concepts. It covers selected applications, such as the Schwarzschild solution and gravitational waves.
LernzielBasic understanding of general relativity, its mathematical foundations (in particular the relevant aspects of differential geometry), and some of the phenomena it predicts (with a focus on black holes).
InhaltIntroduction to the theory of general relativity. The course puts a strong focus on the mathematical foundations, such as differentiable manifolds, the Riemannian and Lorentzian metric, connections, and curvature. It discusses the underlying physical principles, e.g., the equivalence principle, and concepts, such as curved spacetime and the energy-momentum tensor. The course covers some basic applications and special cases, including the Newtonian limit, post-Newtonian expansions, the Schwarzschild solution, light deflection, and gravitational waves.
LiteraturSuggested textbooks:

C. Misner, K, Thorne and J. Wheeler: Gravitation
S. Carroll - Spacetime and Geometry: An Introduction to General Relativity
R. Wald - General Relativity
S. Weinberg - Gravitation and Cosmology
Experimentelle Kernfächer
NummerTitelTypECTSUmfangDozierende
402-0257-00LAdvanced Solid State PhysicsW10 KP3V + 2UW. Wegscheider
KurzbeschreibungThis course is an extension of the introductory course on solid state physics.

The purpose of this course is to learn to navigate the complex collective quantum phases, excitations and phase transitions
that are the dominant theme in modern solid state physics. The emphasis is on the main concepts and on specific experimental
examples, both classic ones and those from recent research.
LernzielThe goal is to study how novel phenomena emerge in the solid state.
InhaltToday's challenges and opportunities in Solid State Physics:
Phase transitions and critical phenomena, Fermi surface instabilities, Superconductors, Magnetism of insulators, Semiconductors
SkriptThe printed material for this course involves: (1) a self-contained script, distributed electronically at semester start. (2) experimental examples (Power Point slide-style) selected from original publications, distributed at the start of every lecture.
LiteraturA list of books will be distributed. Numerous references to useful published scientific papers will be provided.
Voraussetzungen / BesonderesThis course is for students who like to be engaged in active learning. The "exercise classes" are organized in a non-traditional way: following the idea of "less is more", we will work on only about half a dozen topics, and this gives students a chance to take a look at original literature (provided), and to get the grasp of a topic from a broader perspective.

Students report back that this mode of "exercise class" is more satisfying than traditional modes, even if it does not mean less effort.
KompetenzenKompetenzen
Fachspezifische KompetenzenKonzepte und Theoriengeprüft
Verfahren und Technologiengefördert
Methodenspezifische KompetenzenMedien und digitale Technologiengefördert
Problemlösunggefördert
Soziale KompetenzenKommunikationgefördert
Kooperation und Teamarbeitgefördert
Persönliche KompetenzenKreatives Denkengefördert
Kritisches Denkengefördert
402-0442-00LQuantum OpticsW10 KP3V + 2UT. U. Donner
KurzbeschreibungThis course gives an introduction to the fundamental concepts of Quantum Optics and will highlight state-of-the-art developments in this rapidly evolving discipline. The topics covered include the quantum nature of light, semi-classical and quantum mechanical description of light-matter interaction, laser manipulation of atoms and ions, optomechanics and quantum computation.
LernzielThe course aims to provide the knowledge necessary for pursuing research in the field of Quantum Optics. Fundamental concepts and techniques of Quantum Optics will be linked to modern experimental research. During the course the students should acquire the capability to understand currently published research in the field.
InhaltThis course gives an introduction to the fundamental concepts of Quantum Optics and will highlight state-of-the-art developments in this rapidly evolving discipline. The topics that are covered include:

- coherence properties of light
- quantum nature of light: statistics and non-classical states of light
- light matter interaction: density matrix formalism and Bloch equations
- quantum description of light matter interaction: the Jaynes-Cummings model, photon blockade
- laser manipulation of atoms and ions: laser cooling and trapping, atom interferometry,
- further topics: Rydberg atoms, optomechanics, quantum computing, complex quantum systems.
SkriptSelected book chapters will be distributed.
LiteraturText-books:

G. Grynberg, A. Aspect and C. Fabre, Introduction to Quantum Optics
R. Loudon, The Quantum Theory of Light
Atomic Physics, Christopher J. Foot
Advances in Atomic Physics, Claude Cohen-Tannoudji and David Guéry-Odelin
C. Cohen-Tannoudji et al., Atom-Photon-Interactions
M. Scully and M.S. Zubairy, Quantum Optics
Y. Yamamoto and A. Imamoglu, Mesoscopic Quantum Optics
KompetenzenKompetenzen
Konzepte und Theoriengeprüft
Verfahren und Technologiengeprüft
Methodenspezifische KompetenzenAnalytische Kompetenzengeprüft
Medien und digitale Technologiengefördert
Problemlösunggeprüft
Soziale KompetenzenKommunikationgefördert
Kooperation und Teamarbeitgefördert
Persönliche KompetenzenKreatives Denkengeprüft
Kritisches Denkengefördert
402-0402-00LUltrafast Laser Physics Information W10 KP3V + 2UL. Gallmann, S. Johnson, U. Keller
KurzbeschreibungIntroduction to ultrafast laser physics with an outlook into cutting edge research topics such as attosecond science and coherent ultrafast sources from THz to X-rays.
LernzielUnderstanding of basic physics and technology for pursuing research in ultrafast laser science. How are ultrashort laser pulses generated, how do they interact with matter, how can we measure these shortest man-made events and how can we use them to time-resolve ultrafast processes in nature? Fundamental concepts and techniques will be linked to a selection of hot topics in current research and applications.
InhaltThe lecture covers the following topics:

a) Linear pulse propagation: mathematical description of pulses and their propagation in linear optical systems, effect of dispersion on ultrashort pulses, concepts of pulse carrier and envelope, time-bandwidth product

b) Dispersion compensation: technologies for controlling dispersion, pulse shaping, measurement of dispersion

c) Nonlinear pulse propagation: intensity-dependent refractive index (Kerr effect), self-phase modulation, nonlinear pulse compression, self-focusing, filamentation, nonlinear Schrödinger equation, solitons, non-instantaneous nonlinear effects (Raman/Brillouin), self-steepening, saturable gain and absorption

d) Second-order nonlinearities with ultrashort pulses: phase-matching with short pulses and real beams, quasi-phase matching, second-harmonic and sum-frequency generation, parametric amplification and generation

e) Relaxation oscillations: dynamical behavior of rate equations after perturbation

f) Q-switching: active Q-switching and its theory based on rate equations, active Q-switching technologies, passive Q-switching and theory

g) Active modelocking: introduction to modelocking, frequency comb versus axial modes, theory for various regimes of laser operation, Haus master equation formalism

h) Passive modelocking: slow, fast and ideally fast saturable absorbers, semiconductor saturable absorber mirror (SESAM), designs of and materials for SESAMs, modelocking with slow absorber and dynamic gain saturation, modelocking with ideally fast saturable absorber, Kerr-lens modelocking, soliton modelocking, Q-switching instabilities in modelocked lasers, inverse saturable absorption

i) Pulse duration measurements: rf cables and electronics, fast photodiodes, linear system theory for microwave test systems, intensity and interferometric autocorrelations and their limitations, frequency-resolved optical gating, spectral phase interferometry for direct electric-field reconstruction and more

j) Noise: microwave spectrum analyzer as laser diagnostics, amplitude noise and timing jitter of ultrafast lasers, lock-in detection

k) Ultrafast measurements: pump-probe scheme, transient absorption/differential transmission spectroscopy, four-wave mixing, optical gating and more

l) Frequency combs and carrier-envelope offset phase: measurement and stabilization of carrier-envelope offset phase (CEP), time and frequency domain applications of CEP-stabilized sources

m) High-harmonic generation and attosecond science: non-perturbative nonlinear optics / strong-field phenomena, high-harmonic generation (HHG), phase-matching in HHG, attosecond pulse generation, attosecond technology: detectors and diagnostics, attosecond metrology (streaking, RABBITT, transient absorption, attoclock), example experiments

n) Ultrafast THz science: generation and detection, physics in THz domain, weak-field and strong-field applications

o) Brief introduction to other hot topics: relativistic and ultra-high intensity ultrafast science, ultrafast electron sources, free-electron lasers, etc.
SkriptClass notes will be made available.
Voraussetzungen / BesonderesPrerequisites: Basic knowledge of quantum electronics (e. g., 402-0275-00L Quantenelektronik).
KompetenzenKompetenzen
Fachspezifische KompetenzenKonzepte und Theoriengeprüft
Verfahren und Technologiengeprüft
402-0891-00LPhenomenology of Particle Physics IW10 KP3V + 2UP. Crivelli, A. de Cosa
KurzbeschreibungTopics to be covered in Phenomenology of Particle Physics I:
Relativistic kinematics
Decay rates and cross sections
The Dirac equation
From the S-matrix to the Feynman rules of QED
Scattering processes in QED
Experimental tests of QED
Hadron spectroscopy
Unitary symmetries and QCD
QCD and alpha_s running
QCD in e^+e^- annihilation
Experimental tests of QCD in e^+e^- annihilation
LernzielIntroduction to modern particle physics
InhaltTopics to be covered in Phenomenology of Particle Physics I:
Relativistic kinematics
Decay rates and cross sections
The Dirac equation
From the S-matrix to the Feynman rules of QED
Scattering processes in QED
Experimental tests of QED
Hadron spectroscopy
Unitary symmetries and QCD
QCD and alpha_s running
QCD in e^+e^- annihilation
Experimental tests of QCD in e^+e^- annihilation
LiteraturAs described in the entity: Lernmaterialien
402-0448-01LQuantum Information Processing I: Concepts
Dieser theoretisch ausgerichtete Teil QIP I bildet zusammen mit dem experimentell ausgerichteten Teil 402-0448-02L QIP II, die beide im Herbstsemester angeboten werden, im Master-Studiengang Physik das experimentelle Kernfach "Quantum Information Processing" mit total 10 ECTS-Kreditpunkten.
W5 KP2V + 1UJ. Renes
KurzbeschreibungThe course covers the key concepts and formalism of quantum information processing. Topics include quantum algorithms, quantum error correction, quantum cryptography, and quantum metrology, with an emphasis on the power of quantum information processing beyond that of classical information processing. The formalism of quantum states, measurements, and channels is developed in detail.
LernzielBy the end of the course students are able to explain the basic mathematical formalism of quantum mechanics and apply it to quantum information processing problems. They are able to adapt and apply these concepts and methods to analyze and discuss quantum algorithms and other quantum information-processing protocols.
InhaltThe topics covered in the course will include quantum circuits, gate decomposition and universal sets of gates, efficiency of quantum circuits, quantum algorithms (Shor, Grover, Deutsch-Josza,..), stabilizer-based quantum error correction, fault-tolerant designs, the BB84 quantum key distribution protocol, and simple methods of quantum metrology.
SkriptWill be provided.
LiteraturQuantum Computation and Quantum Information
Michael Nielsen and Isaac Chuang
Cambridge University Press
Voraussetzungen / BesonderesA good understanding of finite dimensional linear algebra is recommended.
KompetenzenKompetenzen
Fachspezifische KompetenzenKonzepte und Theoriengeprüft
Verfahren und Technologiengeprüft
Methodenspezifische KompetenzenAnalytische Kompetenzengeprüft
402-0448-02LQuantum Information Processing II: Implementations
Dieser experimentell ausgerichtete Teil QIP II bildet zusammen mit dem theoretisch ausgerichteten Teil 402-0448-01L QIP I, die beide im Herbstsemester angeboten werden, im Master-Studiengang Physik das experimentelle Kernfach "Quantum Information Processing" mit total 10 ECTS-Kreditpunkten.
W5 KP2V + 1UA. Wallraff, J.‑C. Besse
KurzbeschreibungIntroduction to experimental systems for quantum information processing (QIP). Quantum bits. Coherent Control. Measurement. Decoherence. Microscopic and macroscopic quantum systems. Nuclear magnetic resonance (NMR). Photons. Ions and neutral atoms in electromagnetic traps. Charges and spins in quantum dots and NV centers. Charges and flux quanta in superconducting circuits. Novel hybrid systems.
LernzielThroughout the past 20 years the realm of quantum physics has entered the domain of information technology in more and more prominent ways. Enormous progress in the physical sciences and in engineering and technology has allowed us to build novel types of information processors based on the concepts of quantum physics. In these processors information is stored in the quantum state of physical systems forming quantum bits (qubits). The interaction between qubits is controlled and the resulting states are read out on the level of single quanta in order to process information. Realizing such challenging tasks is believed to allow constructing an information processor much more powerful than a classical computer. This task is taken on by academic labs, startups and major industry. The aim of this class is to give a thorough introduction to physical implementations pursued in current research for realizing quantum information processors. The field of quantum information science is one of the fastest growing and most active domains of research in modern physics.
InhaltIntroduction to experimental systems for quantum information processing (QIP).
- Quantum bits
- Coherent Control
- Measurement
- Decoherence
QIP with
- Ions
- Superconducting Circuits
- Photons
- NMR
- Rydberg atoms
- NV-centers
- Quantum dots
SkriptCourse material be made available at www.qudev.ethz.ch and on the Moodle platform for the course. More details to follow.
LiteraturQuantum Computation and Quantum Information
Michael Nielsen and Isaac Chuang
Cambridge University Press
Voraussetzungen / BesonderesThe class will be taught in English language.

Basic knowledge of concepts of quantum physics and quantum systems, e.g from courses such as Phyiscs III, Quantum Mechanics I and II or courses on topics such as atomic physics, solid state physics, quantum electronics are considered helpful.

More information on this class can be found on the web site www.qudev.ethz.ch
Wahlfächer
Physikalische und mathematische Wahlfächer
Auswahl: Festkörperphysik
NummerTitelTypECTSUmfangDozierende
402-0469-67LParametric Phenomena
Findet dieses Semester nicht statt.
W6 KP3GA. Eichler
KurzbeschreibungThere are numerous physical phenomena that rely on time-dependent Hamiltonians (or parametric driving) to amplify, cool, squeeze or couple resonating systems. In this course, we will introduce parametric phenomena in different fields of physics, ranging from classical engineering ideas to devices proposed for quantum neural networks.
LernzielThis course is intended for
- experimentalists who desire to gain a solid theoretical understanding of nonlinear driven-dissipative systems,
- theorists looking to expand their analytical and numerical toolbox,
- any scientist interested to learn what lies beyond the harmonic resonator.

In the course, the students will grasp the ubiquitous nature of parametric phenomena and apply it to both classical and quantum systems. The students will understand both the theoretical foundations leading to the parametric drive as well as the experimental aspect related to the realizations of the effect. Each student will analyze an independent system using the tools acquired in the course and will present his/her insights to the class.
InhaltThis course will provide a general framework for understanding and linking various phenomena, ranging from the child-on-a-swing problem to quantum limited amplifiers, to optical frequency combs, and to optomechanical sensors used in the LIGO experiment. The course will combine theoretical lectures and the study of important experiments through literature.

The students will receive an extended lecture summary as well as numerous MATHEMATICA and Python scripts, including QuTiP notebooks. These tools will enable them to apply analytical and numerical methods to a wide range of systems beyond the duration of the course.
SkriptA full script will be available.
Voraussetzungen / BesonderesThe students should be familiar with wave mechanics as well as second quantization. Following the course requires a laptop with Python and MATHEMATICA installed.
402-0526-00LUltrafast Processes in SolidsW6 KP2V + 1UY. M. Acremann
KurzbeschreibungUltrafast processes in solids are of fundamental interest as well as relevant for modern technological applications. The dynamics of the lattice, the electron gas as well as the spin system of a solid are discussed. The focus is on time resolved experiments which provide insight into pico- and femtosecond dynamics.
LernzielAfter attending this course you understand the dynamics of essential excitation processes which occur in solids and you have an overview over state of the art experimental techniques used to study fast processes.
Inhalt1. Experimental techniques, an overview

2. Dynamics of the electron gas
2.1 First experiments on electron dynamics and lattice heating
2.2 The finite lifetime of excited states
2.3 Detection of lifetime effects
2.4 Dynamical properties of reactions and adsorbents

3. Dynamics of the lattice
3.1 Phonons
3.2 Non-thermal melting

4. Dynamics of the spin system
4.1 Laser induced ultrafast demagnetization
4.2 Ultrafast spin currents generated by lasers
4.3 Landau-Lifschitz-Dynamics
4.4 Laser induced switching

5. Correlated materials
Skriptwill be distributed
Literaturrelevant publications will be cited
Voraussetzungen / BesonderesThe lecture can also be followed by interested non-physics students as basic concepts will be introduced.
402-0535-00LIntroduction to Magnetism Information W6 KP3GA. Vindigni
KurzbeschreibungThis course tackles the fundamental question of why only a few materials exhibit magnetism in Nature. The origin of atomic magnetic moments and the key mechanisms that govern their interactions are justified starting from fundamental principles. In addition, the influence of thermal fluctuations on magnetic ordering is discussed as well as the formalism to describe magnetic resonance phenomena.
LernzielBy the end of this course, students will develop the ability to utilize quantum mechanics concepts to estimate the strength of atomic magnetic moments and understand their reciprocal interactions. They will gain proficiency in interpreting experimental measurements on model systems in terms of material composition and an appropriate, phenomenological spin Hamiltonian. For instance, students will be able to recognize whether the magnetic hysteresis observed in some samples arises from slow dynamics or from a phase transition. Lastly, they will be capable of interpreting the occurrence of abrupt transitions or the emergence of characteristic length scales as resulting from the interplay between competing interactions. Altogether, students will acquire the basic knowledge needed to develop a research project in the field of magnetism or to attend effectively more advanced courses on this topic.
InhaltThe lecture “Introduction to Magnetism” aims at letting students familiarize themselves with the basic principles of quantum and statistical physics that determine the behavior of real magnets. Understanding why only a few materials are magnetic at finite temperature will be the leitmotiv of the course. We will see that defining in a formal way what “being magnetic” means is essential to address this question properly. Theoretical concepts will be applied to a few selected nano-sized magnets, which will serve as clean reference systems.
Topics:
- Magnetism in atoms (quantum-mechanical origin of atomic magnetic moments, intra-atomic exchange interaction)
- Magnetism in solids (mechanisms producing inter-atomic exchange interaction in solids, crystal field)
- Magnetic order at finite temperatures (Ising, XY, and Heisenberg models, low-dimensional magnetism)
- Spin precession and relaxation (Larmor precession, resonance phenomena, quantum tunneling, Bloch equation, superparamagnetism)
SkriptLearning material will be made available through Moodle and through the ETH JupyterHub.
Voraussetzungen / BesonderesStudents are assumed to possess a basic background knowledge in quantum mechanics, solid-state and statistical physics as well as classical electromagnetism.
Students will have the opportunity to self-assess their understanding through quizzes and interactive tutorials, mostly inspired by topics of current research in nanoscale magnetism.
KompetenzenKompetenzen
Fachspezifische KompetenzenKonzepte und Theoriengeprüft
Verfahren und Technologiengefördert
Methodenspezifische KompetenzenAnalytische Kompetenzengeprüft
Medien und digitale Technologiengefördert
Problemlösunggefördert
Persönliche KompetenzenKreatives Denkengefördert
Kritisches Denkengeprüft
Selbststeuerung und Selbstmanagement gefördert
402-0595-00LSemiconductor NanostructuresW6 KP2V + 1UT. M. Ihn
KurzbeschreibungDer Kurs umfasst die Grundlagen der Halbleiternanostrukturen, z.B. Materialherstellung, Bandstrukturen, 'bandgap engineering' und Dotierung, Feldeffekttransistoren. Aufbauend auf zweidimensionalen Elektronengasen wird dann der Quantenhalleffekt besprochen, sowie die Physik der gängigen Halbleiternanostrukturen, d.h. Quantenpunktkontakte, Aharonov-Bohm Ringe und Quantendots, behandelt.
LernzielZiel der Vorlesung ist das Verständnis von vier Schlüsselphänomenen des Elektronentransports in Halbleiter-Nanostrukturen. Dazu zählen
1. der ganzzahlige Quantenhalleffekt
2. die Quantisierung des Leitwerts in Quantenpunktkontakten
3. der Aharonov-Bohm Effekt
4. der Coulomb-Blockade Effekt in Quantendots
Inhalt1. Einführung und Überblick
2. Halbleiterkristalle: Herstellung, Molekularstrahlepitaxie
3. Bandstrukturen von Halbleitern
4. k.p-Theorie, Elektronendynamik in der Näherung der effektiven Masse, Envelope Funktionen
5. Heterostrukturen und 'band engineering', Dotierung
6. Oberflächen und Metall-Halbleiter Kontakte, Fabrikation von Nanostrukturen
7. Heterostrukturen und zweidimensionale Elektronengase
8. Drude Transport und Streumechanismen
9. Graphen Einzel- und Doppelschichten
10. Elektronentransport in Quantenpunktkontakten; Leitwertquantisierung, Landauer-Büttiker Beschreibung, ballistische Transportexperimente
11. Interferenzeffekte in Aharonov-Bohm Ringen
12. Elektron im Magnetfeld, Shubnikov-de Haas Effekt
13. Ganzzahliger Quantenhalleffekt
14. Quantendots, Coulombblockade
SkriptT. Ihn, Semiconductor Nanostructures, Quantum States and Electronic Transport, Oxford University Press, 2010.
LiteraturNeben dem Vorlesungsskript können folgende Bücher empfohlen werden:
1. J. H. Davies: The Physics of Low-Dimensional Semiconductors, Cambridge University Press (1998)
2. S. Datta: Electronic Transport in Mesoscopic Systems, Cambridge University Press (1997)
3. D. Ferry: Transport in Nanostructures, Cambridge University Press (1997)
4. T. M. Heinzel: Mesoscopic Electronics in Solid State Nanostructures: an Introduction, Wiley-VCH (2003)
5. Beenakker, van Houten: Quantum Transport in Semiconductor Nanostructures, in: Semiconductor Heterostructures and Nanostructures, Academic Press (1991)
6. Y. Imry: Introduction to Mesoscopic Physics, Oxford University Press (1997)
Voraussetzungen / BesonderesDie Vorlesung richtet sich an alle Physikstudierenden nach dem Bachelorabschluss. Grundlagen in der Festkörperphysik sind erforderlich, ambitionierte Studierende im fünften Semester können der Vorlesung aber auch folgen. Die Vorlesung eignet sich auch für das Doktoratsstudium. Der Kurs wird auf Englisch gehalten.
KompetenzenKompetenzen
Fachspezifische KompetenzenKonzepte und Theoriengeprüft
Verfahren und Technologiengeprüft
Methodenspezifische KompetenzenAnalytische Kompetenzengeprüft
Medien und digitale Technologiengeprüft
Problemlösunggefördert
Soziale KompetenzenKommunikationgefördert
Selbstdarstellung und soziale Einflussnahmegeprüft
Sensibilität für Vielfalt gefördert
Persönliche KompetenzenKreatives Denkengeprüft
Kritisches Denkengeprüft
Integrität und Arbeitsethikgeprüft
Selbststeuerung und Selbstmanagement gefördert
402-0317-00LSemiconductor Materials: Fundamentals and FabricationW6 KP2V + 1US. Schön, W. Wegscheider
KurzbeschreibungThis course gives an introduction into the fundamentals of semiconductor materials. The main focus is on state-of-the-art fabrication and characterization methods. The course will be continued in the spring term with a focus on applications.
LernzielBasic knowledge of semiconductor physics and technology. Application of this knowledge for state-of-the-art semiconductor device processing
Inhalt1. Fundamentals of Solid State Physics
1.1 Semiconductor materials
1.2 Band structures
1.3 Carrier statistics in intrinsic and doped semiconductors
1.4 p-n junctions
1.5 Low-dimensional structures
2. Bulk Material growth of Semiconductors
2.1 Czochalski method
2.2 Floating zone method
2.3 High pressure synthesis
3. Semiconductor Epitaxy
3.1 Fundamentals of Epitaxy
3.2 Molecular Beam Epitaxy (MBE)
3.3 Metal-Organic Chemical Vapor Deposition (MOCVD)
3.4 Liquid Phase Epitaxy (LPE)
4. In situ characterization
4.1 Pressure and temperature
4.2 Reflectometry
4.3 Ellipsometry and RAS
4.4 LEED, AES, XPS
4.5 STM, AFM
5. The invention of the transistor - Christmas lecture
Skripthttps://moodle-app2.let.ethz.ch/course/view.php?id=20749
Voraussetzungen / BesonderesThe "compulsory performance element" of this lecture is a short presentation of a research paper complementing the lecture topics. Several topics and corresponding papers will be offered on the moodle page of this lecture.
KompetenzenKompetenzen
Fachspezifische KompetenzenKonzepte und Theoriengefördert
Verfahren und Technologiengefördert
Methodenspezifische KompetenzenAnalytische Kompetenzengefördert
Soziale KompetenzenKommunikationgefördert
Selbstdarstellung und soziale Einflussnahmegefördert
402-0447-00LQuantum Science with Superconducting Circuits
Findet dieses Semester nicht statt.
W6 KP2V + 1UA. Wallraff
KurzbeschreibungSuperconducting Circuits provide a versatile experimental platform to explore the most intriguing quantum-physical phenomena and constitute one of the prime contenders to build quantum computers. Students will get a thorough introduction to the underlying physical concepts, the experimental setting, and the state-of-the-art of quantum computing in this emerging research field.
LernzielBased on today’s most advanced solid state platform for quantum control, the students will learn how to engineer quantum coherent devices and how to use them to process quantum information. The students will acquire both analytical and numerical methods to model the properties and phenomena observed in these systems. The course is positioned at the intersection between quantum physics and engineering.
InhaltIntroduction to Quantum information Processing -- Superconducting Qubits -- Quantum Measurements -- Experimental Setup & Noise Mitigation -- Open Quantum Systems -- Multi-Qubit Systems: Entangling gates & Characterization -- Quantum Error Correction -- Near-term Applications of Quantum Computers
Voraussetzungen / BesonderesAll students and researchers with a general interest in quantum information science, quantum optics, and quantum engineering are welcome to this course. Basic knowledge of quantum physics is a plus, but not a strict requirement for the successful participation in this course.
Auswahl: Quantenelektronik
NummerTitelTypECTSUmfangDozierende
402-0442-05LAdvanced Topics in Quantum Optics Belegung eingeschränkt - Details anzeigen
Findet dieses Semester nicht statt.
W4 KP2GT. Esslinger
KurzbeschreibungThe lecture will cover current topics and scientific papers in the wider field of quantum optics in an interactive format. First, the research area will be introduced, then several papers of this field will be presented by the students in the style of a journal club. Selected papers will be contrasted and their strengths and weaknesses discussed by the students in panel discussions. Furthermore, r
LernzielThe aim of the lecture is to deepen and broaden the knowledge about current research in the field of quantum optics. In addition, it will also be discussed and critically examined how research results are communicated via publications and lectures and which techniques are used in the process.
InhaltWe will select topical fields in quantum optics and quantum science and discuss recently published work.

Topics:
- Atoms or ions-based quantum computing
- Quantum simulation
- Opto-mechanics
- Driven and dissipative quantum systems
- Cavity based atom-light interaction
- Topological photonics

The interactive part of the lecture will include presentations of recent papers, panel discussions of recent papers and the writing of a critical assessment of an arXiv paper in the style of a referee report.
402-0444-00LDissipative Quantum Systems
Findet dieses Semester nicht statt.
W6 KP2V + 1UA. Imamoglu
KurzbeschreibungThis course builds up on the material covered in the Quantum Optics course. The emphasis will be on quantum optics in condensed-matter systems.
LernzielThe course aims to provide the knowledge necessary for pursuing advanced research in the field of Quantum Optics in condensed matter systems. Fundamental concepts and techniques of Quantum Optics will be linked to experimental research in systems such as quantum dots, exciton-polaritons, quantum Hall fluids and graphene-like materials.
InhaltDescription of open quantum systems using master equation and quantum trajectories. Decoherence and quantum measurements. Dicke superradiance. Dissipative phase transitions. Spin photonics. Signatures of electron-phonon and electron-electron interactions in optical response.
SkriptLecture notes will be provided
LiteraturC. Cohen-Tannoudji et al., Atom-Photon-Interactions (recommended)
Y. Yamamoto and A. Imamoglu, Mesoscopic Quantum Optics (recommended)
A collection of review articles (will be pointed out during the lecture)
Voraussetzungen / BesonderesMasters level quantum optics knowledge
KompetenzenKompetenzen
Fachspezifische KompetenzenKonzepte und Theoriengeprüft
Methodenspezifische KompetenzenAnalytische Kompetenzengeprüft
Problemlösunggeprüft
Soziale KompetenzenKooperation und Teamarbeitgeprüft
Persönliche KompetenzenKreatives Denkengeprüft
Kritisches Denkengeprüft
402-0457-00LQuantum Technologies for Searches of New Physics
Findet dieses Semester nicht statt.
W6 KP2V + 1UP. Crivelli
KurzbeschreibungRecent years have witnessed incredible progress in the development of new quantum technologies driven by their application in quantum information, metrology, high precision spectroscopy and quantum sensing. This course will present how these emerging technologies are powerful tools to address open questions of the Standard Model in a complementary way to what is done at the high energy frontier.
LernzielThe aim of this course is to equip students of different backgrounds with a solid base to follow this rapidly developing and exciting multi-disciplinary field.
InhaltThe first lectures will be dedicated to review the open questions of the Standard Model and the different Beyond Standard Model extensions which can be probed with quantum technologies. This will include searches for dark sector, dark matter, axion and axion-like particles, new gauge bosons (e.g Dark photons) and extra short-range forces.

The main part of the course will introduce the following (quantum) technologies and systems, and how they can be used for probing New Physics.
- Cold atoms
- Trapped ions
- Atoms interferometry
- Atomic clocks
- Cold molecules and molecular clocks
- Exotic Atoms
- Anti-matter
- Quantum Sensors
Voraussetzungen / BesonderesThe preceding attendance of introductory particle physics, quantum mechanics and quantum electronics courses at the bachelor level is recommended.
402-0464-00LOptical Properties of SemiconductorsW8 KP2V + 2UG. Scalari, P. Anantha Murthy
KurzbeschreibungThis course presents a comprehensive discussion of optical processes in semiconductors.
LernzielThe rich physics of the optical properties of semiconductors, as well as the advanced processing available on these material, enabled numerous applications (lasers, LEDs and solar cells) as well as the realization of new physical concepts. Systems that will be covered include quantum dots, exciton-polaritons, quantum Hall fluids and graphene-like materials.
InhaltElectronic states in III-V materials and quantum structures, optical transitions, excitons and polaritons, novel two dimensional semiconductors, spin-orbit interaction and magneto-optics.
Voraussetzungen / BesonderesPrerequisites: Quantum Mechanics I, Introduction to Solid State Physics
402-0465-58LIntersubband OptoelectronicsW6 KP2V + 1UG. Scalari, J. Faist
KurzbeschreibungIntersubband transitions in quantum wells are transitions between states created by quantum confinement in ultra-thin layers of semiconductors. Because of its inherent taylorability, this system can be seen as the "ultimate quantum designer's material".
LernzielThe goal of this lecture is to explore both the rich physics as well as the application of these system for sources and detectors. In fact, devices based on intersubband transitions are now unlocking large area of the electromagnetic spectrum.
InhaltThe lecture will treat the following chapters:
- Introduction: intersubband optoelectronics as an example of quantum engineering
-Technological aspects
- Electronic states in semiconductor quantum wells
- Intersubband absorption and scattering processes
- Mid-Ir and THz ISB Detectors
-Mid-infrared and THz photonics: waveguides, resonators, metamaterials
- Quantum Cascade lasers:
-Mid-IR QCLs
-THZ QCLs (direct and non-linear generation)
-further electronic confinement: interlevel Qdot transitions and magnetic field effects
-Strong light-matter coupling in Mid-IR and THz range
SkriptThe reference book for the lecture is "Quantum Cascade Lasers" by Jerome Faist , published by Oxford University Press.
LiteraturMostly the original articles, other useful reading can be found in:

-E. Rosencher and B. Vinter, Optoelectronics , Cambridge Univ. Press
-G. Bastard, Wave mechanics applied to semiconductor heterostructures, Halsted press
Voraussetzungen / BesonderesRequirements: A basic knowledge of solid-state physics and of quantum electronics.
  •  Seite  1  von  7 Nächste Seite Letzte Seite     Alle