Quantum Mechanics from Condensed Matter to Computing
Informacje ogólne
| Kod przedmiotu: | 1100-QMCMC | Kod Erasmus / ISCED: | (brak danych) / (brak danych) |
| Nazwa przedmiotu: | Quantum Mechanics from Condensed Matter to Computing | ||
| Jednostka: | Wydział Fizyki | ||
| Grupy: |
Fizyka, II stopień; przedmioty z listy "Wybrane zagadnienia fizyki współczesnej" Physics (Studies in English), 2nd cycle; courses from list "Topics in Contemporary Physics" Physics (Studies in English); 2nd cycle Przedmioty do wyboru dla doktorantów; |
||
| Punkty ECTS i inne: |
7.50  |
||
| Język prowadzenia: | angielski | ||
Zajęcia w cyklu "Semestr letni 2021/22" (zakończony)
| Okres: | 2022-02-21 - 2022-06-15 |
 
 zobacz plan zajęć |
| Typ zajęć: |
Ćwiczenia, 30 godzin  więcej informacji Wykład, 30 godzin więcej informacji |
|
| Koordynatorzy: | Marcin Napiórkowski | |
| Prowadzący grup: | Marcin Napiórkowski | |
| Strona przedmiotu: | https://qmath.ku.dk/teaching/4eu/ | |
| Lista studentów: | (nie masz dostępu) | |
| Zaliczenie: | Egzamin | |
| Tryb prowadzenia: | zdalnie |
|
| Skrócony opis: |
The goal is to provide the students with a blended learning approach to the course content on the mathematics of quantum theory with special emphasis on complex quantum many-body systems and quantum information theory. The Main intended learning outcomes include an overview over the latest developments in those fields, the capability to analyze the performance and complexity of a given quantum optimization algorithm as well as how to efficiently benchmark and certify the functioning of a quantum information processing device. Furthermore, the course will help the participants to develop competencies to engage in self-organized cross-university and interdisciplinary collaborations via online groupwork as well as to give an receive peer-feedback on results. Inviting external experts in the field will also give young researchers in the field the opportunity to grow their professional network considerably. | |
| Pełny opis: |
We are currently witnessing the second quantum revolution and with it the advent of quantum technological devices for information processing purposes. Understanding these systems and their capabilities as well as developing robust algorithms for them, requires a fundamental understanding of complex quantum many-body systems as well as ways to characterize their properties efficiently. Within this course, we will help the participants to obtain proficiency in all of these aspects of quantum theory. A tentative list of topics include A) Complex quantum many-body systems: -Mathematical description of many-body systems -Properties of Fermi and Bose gases B) Identification and certification of quantum systems -Quantum state tomography -Self-testing For each of these topics, we will provide introductory lectures to get students acquainted with the topics before entering into the in-person phase, where experts and practitioners of these fields will give further insight. | |
| Uwagi: |
The course will consist of three phases. Phase 1: March 1- May 13, 2022: Online lectures (approximately one two hour lectures every other week, in total 6 lectures) Phase 2: May 13- June 13, 2022: Students work on assignments which will be presented at a poster session at the physical meeting. Phase 3: June 13 -June 17, 2022: Physical Master Class (Approximately 24 hours of lectures plus 5 hours exercises) The Physical Master Class will take place in Copenhagen. Registered students will get financial support for travel and accommodation by the 4EU+ programme. | |
Właścicielem praw autorskich jest Uniwersytet Warszawski.