게시물검색
Course Name Course number Language Credts Branch Course outline
Topics in solid state physics 3 Korean course Major 본원 -
Course Name

Topics in solid state physics

Summary

Lecture Objectives

  • Throughout this course, we are providing a comprehensive understanding of quantum phenomena of condensed matter (thermal, electrical, magnetic, and etc.) within crystalline materials. In addition, we will also explain the quantum phenomena in solid state, focusing on theoretical and experimental techniques in cutting-edge researches. The topic of lecture includes 1. Analyzing the structure of condensed matter 2. Exploring the concepts of the free electron model 3. Investigating the thermal properties and phonon 4. Understanding the magnetism and spin.
Optics 3 Korean course Major 본원 -
Course Name

Optics

Summary

Lecture Objectives

  • Many quantum information experiments can be implemented using optical experiments. In this course, you will understand the basic principles of optics and acquire knowledge for applying it to applied research. In particular, you will learn the necessary content for designing and conducting various optical experiments, including electromagnetic waves, wave equations, linear optical systems, wave interference, polarization, interference, diffraction, and more.
Single photon sensors 3 Korean course Major 본원 -
Course Name

Single photon sensors

Summary

Lecture Objectives

  • This course introduces the types and basic principles of single-photon sensors, which are one of the key elements in quantum sensing, measurement, communication, cryptography, and computing. In addition, in this course, device structures, measurement methods, main characteristics, application fields, trends, and state-of-the-art technologies are covered.
Quantum sensing and metrology 3 Korean course Major 본원 -
Course Name

Quantum sensing and metrology

Summary

Lecture Objectives

  • The primary objective here is to comprehend the fundamental principles of quantum technologies that enable us to surpass the classical sensing limits in sensing and metrology, making use of quantum systems. This course will cover the elementary quantum theory related to sensing and metrology, in addition to quantum parameter estimation and quantum measurement theory. Furthermore, we will discuss a variety of examples that show the connection between these fundamental theories and their applications in quantum sensing and metrology.
Introduction to Quantum Materials, Devices, and Fabrication 3 Korean course Major 본원 -
Course Name

Introduction to Quantum Materials, Devices, and Fabrication

Summary

Lecture Objectives

  • This course reviews the materials and devices that utilize quantum mechanics to realize quantum entangled states to realize "qubits" for quantum information technology. Fabrication techniques of various types of devices will also be discussed. 1) Introduction to quantum materials (nano-structure, superconductors, and quantum magnets), discussing their underlying principles, pros and cons, and synthesis methods. 2) Introduction to quantum devices (optical, atomic, ionic, superconductor, nano-structure), focusing on their operating principles and realization. Also discusses essential fabrication techniques. 3) Understand the measurement methods for each quantum devices and a brief review on state-of-the-art quantum computing technology.
Quantum transport and measurement 3 Korean course Major 본원 -
Course Name

Quantum transport and measurement

Summary

Lecture Objectives

  • Solid-state quantum devices play key roles in the quantum information technology, including quantum computation and quantum communication. In this curriculum, we cover electronic transports and measurement techniques in solid matters in quantum phenomena. The following includes a list of topics: -Electronic transport in correlated quantum states (quantum Hall effect, Shubnikov-De Hass oscillation, Josephson effect) -Coherent transport (Weak locaization, Aharnov-Bohm effect) -Classical transport (Drude model, Coulomb blockade) -Electronic measurement techniques (Four-probe measurement, Lock-in measurement, Magnetotransport measurement, Cryogenic techniques, and etc.) -Electronic precision measurement (Comparison measurement, Uncertainty evaluation) -Noise measurements (extrinic electronic noise, tribo-electric effect, intrinsic electronic noise)
Quantum Optics 3 Korean course Major 본원 -
Course Name

Quantum Optics

Summary

Lecture Objectives

  • This course explores the fundamental principles of quantum mechanical treatment of light, an electromagnetic wave. Utilizing the framework of linear algebra and the formalism established in quantum mechanics, you will learn the quantization of light, various quantum states, and their respective quantum features, as well as quantum interferometry. We also discuss the generation, control, and measurement of quantum states of light and light-matter interaction in the framework of quantum open system. Moreover, the course covers various quantum information applications, including quantum computing, communication, and sensing, leveraging the properties of quantum light.
Quantum Physics 3 Korean course Major 본원 -
Course Name

Quantum Physics

Summary

Lecture Objectives

  • Quantum physics, established in the early 20th century, offers a completely new perspective on natural phenomena. In this course, we will introduce the quantum physics that forms the foundation of quantum information science. In particular, we will focus on learning the necessary content to understand quantum information, such as quantum superposition, quantum entanglement, quantum measurement and state collapse, and the uncertainty principle.
Quantum Physics 3 Korean course Major 본원 -
Course Name

Quantum Physics

Summary

Lecture Objectives

  • Quantum physics, established in the early 20th century, offers a completely new perspective on natural phenomena. In this course, we will introduce the quantum physics that forms the foundation of quantum information science. In particular, we will focus on learning the necessary content to understand quantum information, such as quantum superposition, quantum entanglement, quantum measurement and state collapse, and the uncertainty principle.
Spin & Ultrafast Structural Dynamics of Quantum Materials 3 Korean course Major 본원 -
Course Name

Spin & Ultrafast Structural Dynamics of Quantum Materials

Summary

Lecture Objectives

  • The course covers basics of the spin and structural dynamics in quantum materials based on learning how to measure and analyze spin behaviors using the inelastic neutron scattering and the magnetic resonance spectroscopy method, as well as measuring and analyzing ultrafast structural dynamics using time-resolved electron diffraction. By understanding the relationship between the spin dynamics and structural dynamics of quantum materials, the course provides essential information for finding new quantum materials.
The Electronic Structure Calculation of Quantum Materials 3 Korean course Major 본원 -
Course Name

The Electronic Structure Calculation of Quantum Materials

Summary

Lecture Objectives

  • The course provides basic knowledge of electronic structure calculation based on density functional theory (DFT) and actual DFT code practice. Students will learn how to predict the structure and magnetization of materials as well as how to analyse spectroscopy and transport data obtained from various experimental works.
Introduction to Quantum Information 3 Korean course Major 본원 -
Course Name

Introduction to Quantum Information

Summary

Lecture Objectives

  • Learn the principles and methods of information processing using quantum systems governed by the principles and laws of quantum mechanics. A general introduction to the field of quantum information, such as qubits, quantum superposition and entanglement, quantum computing, quantum algorithms, quantum communication, quantum error correction, and quantum sensing.
Introduction to Quantum Information 3 Korean course Major 본원 -
Course Name

Introduction to Quantum Information

Summary

Lecture Objectives

  • Learn the principles and methods of information processing using quantum systems governed by the principles and laws of quantum mechanics. A general introduction to the field of quantum information, such as qubits, quantum superposition and entanglement, quantum computing, quantum algorithms, quantum communication, quantum error correction, and quantum sensing.
Photonics for Quantum Information 3 Korean course Major 본원 -
Course Name

Photonics for Quantum Information

Summary

Lecture Objectives

  • This course deals with modern optics and optical signal processing techniques required for various types of quantum information processing. It describes the underlying principles for analysis and control over the space-time distribution, frequency, and entanglement of photons, utilizing nonlinear optics, micro/nano-photonics, and fiber optics.
Quantum Information Theory 3 Korean course Major 본원 -
Course Name

Quantum Information Theory

Summary

Lecture Objectives

  • In this class, we cover the utilization of the characteristics of quantum physics for the information processing from the perspective of information theory. We explorer theories that handle the resources of quantum information, such as quantum state, quantum measurement, quantum Shannon theory, and so on. Students will have a chance to understand the fundamental principles that enable quantum advantages in comparison to traditional information processing capabilities.
Special Topics on Quantum Information 3 Korean course Major 본원 -
Course Name

Special Topics on Quantum Information

Summary

Lecture Objectives

  • Special topics on quantum information includes the latest research on quantum information theory, quantum algorithms, quantum computing, quantum simulation, quantum communication, quantum internet, quantum cryptography, quantum sensing, quantum measurement, quantum computing, quantum AI, and quantum machine learning. Lecture will be held in a variety of ways depending on the subject.
Quantum Computing and Quantum Simulation 3 Korean course Major 본원 -
Course Name

Quantum Computing and Quantum Simulation

Summary

Lecture Objectives

  • Based on the understanding of the operating principles of various qubit devices constituting a quantum computer, this lecture covers the concepts of quantum gates, quantum circuits, quantum adiabatic calculation, quantum algorithms, quantum advantages, and quantum error correction and shows examples of quantum simulations solving problems that are difficult to solve with conventional computers.
Quantum Computing Programing and Algorithm 3 Korean course Major 본원 -
Course Name

Quantum Computing Programing and Algorithm

Summary

Lecture Objectives

  • In this class, (1) we cover the basic programming skill required to simulate large-scale quantum circuits on high performance (classical) computing resource. (2) Then, in-depth logistic for utilization of variational quantum algorithms (VQA) will be presented, particularly to solve realistic partial differential equation problems such as empirical simulations of nano-scale materials. (3) Students will also have a chance to take a look into the practicality of VQA by comparing its performance with those of classical numerical algorithms that conduct similar tasks.
Quantum Communication and Quantum Cryptography 3 Korean course Major 본원 -
Course Name

Quantum Communication and Quantum Cryptography

Summary

Lecture Objectives

  • This lecture deals with the basics of quantum optics, quantum nonlinear materials, quantum entanglement, generation and measurement of entangled photon pairs, which are the basis of quantum communication and quantum cryptography, and also covers quantum transmission, quantum repeaters, quantum communication based on entangled photon pairs, quantum networks, and quantum internet, basic ideas of quantum cryptography, cryptographic concepts and tools, quantum key distribution protocols, security proofs and systems, and the latest quantum cryptography work and protocols.
Quantum Communication and Quantum Cryptography 3 Korean course Major 본원 -
Course Name

Quantum Communication and Quantum Cryptography

Summary

Lecture Objectives

  • Quantum technology is currently developing into an industrialized technology beyond basic scientific research, specially in the fields of quantum computing, quantum communication, and quantum sensing. Embedded systems are widely used not only in basic scientific research experiment to uncover the fundamental principles of quantum phenomena, but also in system development for commercial system. In this course, the goal is to develop the ability to automate quantum experiment setup and to implement a control unit for quantum application systems using FPGA.
Atomic Physics 3 Korean course Major 본원 -
Course Name

Atomic Physics

Summary

Lecture Objectives

  • Various atomic systems serve as fundamental platforms for quantum application technologies. Despite differences in control schemes among these atomic platforms, they all stem from the core principles developed in atomic physics. In this course, we will delve into the quantum mechanical fundamentals of general atomic systems and explore how quantum technology has evolved from this foundation. Moreover, we will learn about the basic numerical tools that enable the simulation of simple atomic systems for quantum applications.
Vacuum Instrument and Lab Electronics 3 Korean course Major 본원 -
Course Name

Vacuum Instrument and Lab Electronics

Summary

Lecture Objectives

  • Quantum experiments are mostly conducted in ultra-high vacuum and cryogenic temperatures. The principle of vacuum generation [pump etc], vacuum measuring device, and vacuum environment device [chamber and electrical, optical, and mechanical feed-throughs etc] are lectured. In addition, basic skills for measuring electrical signals and controlling experimental devices [Noise measuring, AC/DC power supply, Arduino, Lab-automation etc] are delivered.
Vacuum Instrument and Lab Electronics 3 Korean course Major 본원 -
Course Name

Vacuum Instrument and Lab Electronics

Summary

Lecture Objectives

  • Quantum experiments are mostly conducted in ultra-high vacuum and cryogenic temperatures. The principle of vacuum generation [pump etc], vacuum measuring device, and vacuum environment device [chamber and electrical, optical, and mechanical feed-throughs etc] are lectured. In addition, basic skills for measuring electrical signals and controlling experimental devices [Noise measuring, AC/DC power supply, Arduino, Lab-automation etc] are delivered.
Materials for Qubits 3 Korean course Major 본원 -
Course Name

Materials for Qubits

Summary

Lecture Objectives

  • The course aims to teach the operating principles and basic physics of the representative four qubit types and related materials such as superconductor qubits, ion trap qubits, silicon quantum dot qubits, and diamond vacancy qubits. It also introduces newly developing qubit types and potential materials including topological qubits.