Quantum Information Theory
A.Y. 2025/2026
Learning objectives
The course illustrates the physical origin of information theory and provides notions of modern quantum mechanics, with emphasis on
implementations in atomic and quantum-optical systems. It also illustrates the most recent development of quantum information theory
and the possible implementations of new protocols for transmission and manipulation of information.
implementations in atomic and quantum-optical systems. It also illustrates the most recent development of quantum information theory
and the possible implementations of new protocols for transmission and manipulation of information.
Expected learning outcomes
Students will learn:
1. how to recognize information as a physical resource, with examples where the quantum nature of physical systems improve
performances;
2. how to characterize entanglement of bipartite systems;
3. how to characterize nonlocality of physical systems and how to write Bell inequalities;
4. how to apply the notion of quantum estimation theory to find ultimate bound to precision of quantum measurements;
5. how to describe and quantify quantum enhancement in teleportation, dense coding, quantum cryptography and quantum metrology;
6. he/she will able to state the theorems of Naimark, Kraus and Shannon, and will be able to provide a mathematical proof of the first
two.
1. how to recognize information as a physical resource, with examples where the quantum nature of physical systems improve
performances;
2. how to characterize entanglement of bipartite systems;
3. how to characterize nonlocality of physical systems and how to write Bell inequalities;
4. how to apply the notion of quantum estimation theory to find ultimate bound to precision of quantum measurements;
5. how to describe and quantify quantum enhancement in teleportation, dense coding, quantum cryptography and quantum metrology;
6. he/she will able to state the theorems of Naimark, Kraus and Shannon, and will be able to provide a mathematical proof of the first
two.
Lesson period: Second semester
Assessment methods: Esame
Assessment result: voto verbalizzato in trentesimi
Single course
This course cannot be attended as a single course. Please check our list of single courses to find the ones available for enrolment.
Course syllabus and organization
Single session
Responsible
Lesson period
Second semester
Professor(s)
Reception:
By appointment only (upon agreement by email)
LITA building, room A5/C11