PhD program
Quantum Technologies

Quantum Technologies

QUALIFICATION

  • Scientific and pedagogical direction - Doctor of Philosophy (PhD)

MODEL OF GRADUATING STUDENT

Program passport

Speciality Name
Quantum Technologies
Speciality Code
8D05312
Faculty
of Physics and Technology

disciplines

disciplines

Quantum communications and the quantum internet
  • Type of control - [RK1+MT+RK2+Exam] (100)
  • Description - The goal of the discipline is to provide in-depth knowledge about the principles of building scalable quantum networks and the quantum internet. Expected learning outcomes: 1) analyze MDI-QKD architectures; 2) evaluate the capabilities of quantum repeaters; 3) model scalable network structures; 4) investigate attack resistance; 5) develop new key distribution protocols. During the study of the course, doctoral students will explore the following aspects: MDI-QKD, quantum repeaters, quantum internet, network topologies, security of distributed quantum systems.

Quantum networks and scalability
  • Type of control - [RK1+MT+RK2+Exam] (100)
  • Description - The goal of the discipline is provide in-depth knowledge about the principles of building scalable quantum networks and the quantum internet. Expected learning outcomes: 1) analyze MDI-QKD architectures; 2) evaluate the capabilities of quantum repeaters; 3) model scalable network structures; 4) investigate attack resistance; 5) develop new key distribution protocols. During the study of the course, doctoral students will explore the following aspects: MDI-QKD, quantum repeaters, quantum internet, network topologies, security of distributed quantum systems.

Quantum sensors and precision metrology
  • Type of control - [RK1+MT+RK2+Exam] (100)
  • Description - The goal of the discipline is to provide in-depth knowledge of quantum methods of ultra-precise measurements and their application in geophysics, navigation and security. Expected learning outcomes: 1) analyze the principles of atomic interferometry; 2) apply laser cooling and confinement methods to atoms; 3) evaluate the accuracy of quantum measurements; 4) model phase shifts in atomic systems; 5) develop new quantum sensor solutions. During the study of the course, doctoral students will explore the following aspects: Magneto-optical traps (MOT), Ramsey-Bohr-Chu interferometer, cold atoms, gravimetry, single photon detectors, temporal correlation, quantum imaging.

Quantum Systems Engineering
  • Type of control - [RK1+MT+RK2+Exam] (100)
  • Description - The goal of the discipline is to provide knowledge on the design and integration of complex quantum systems into the national infrastructure. Expected learning outcomes: 1) develop the architecture of quantum complexes; 2) integrate cryogenic, optical, and electronic systems; 3) assess operational risks; 4) manage the lifecycle of quantum installations; 5) implement prototypes and pilot projects. During the study of the course, doctoral students will explore the following aspects: Cryogenics, low-noise electronics, fiber optics, safety standards, industrial integration of QKD and quantum sensors.

Data for 2023-2026 years

INTERNSHIPS

Pedagogical
  • Type of control - Защита практики
  • Description -

Research
  • Type of control - Защита практики
  • Description -

Data for 2023-2026 years