Training USTians with pride by promotinga creative educational environment

Secure world-leading educational competitiveness

Discovering creative talent and to become real USTians
Establishment of UST21 education system

Become a university with industry-academia-research integration

Strengthening the cooperation between UST-GFRIs-corporations
Strengthen the cooperation between GFRIs
Support business start-ups with GFRI-based technologies

Establish global status as a national research university

Improving brand value
Improving cooperation network

Establish creative knowledge management system

Providing creative educational environment by applying cutting-edge technology
Improving management effectiveness


Energy conversion engineering has been one of the central themes in the development of the engineering profession. It is concerned with the transformation of energy from sources such as fossil and nuclear fuels and the sun into conveniently usable forms such as electrical energy, rotational and propulsive energy, and heating and cooling. A multitude of choices and challenges face the modern energy conversion engineer. A few years ago major segments of the energy conversion industry were settled into a pattern of slow innovation. Now, However, energy conversion is seeing very significant scholarship. because of the oil embargo of the 1970s, high fuel prices, and threatened shortages. Also, the public and country legislatures have begun to recognize that air pollution produced by factories, power plants, and automobiles, and other forms of environmental pollution are harmful. Moreover, the limitations of the Earth’s resources and of the environment are coming into clearer focus. These and other factors have been helping to create a more favorable climate for consideration, if not total acceptance, of energy conversion alternatives and new concepts. So, more open attitudes have become established. New as well as previously shelved ideas are now being considered or reconsidered, tested, and sometimes implemented. We are living in a rapidly changing world that requires continuing adaptation of old technologies and the development of new ones. Energy conversion engineering is a more stimulating, complex, and viable field today because of this altered climate.


Course Name (Kor/Eng)

플라즈마공학 (Plasma Engineering)

Course Details

Course Details
캠퍼스, 학위과정, 학점, 이수구분, 강의형태, 강의방법, 주관교수로 구분하여 안내합니다.
Campus Korea Electrotechnology Research Institute
Academic Curriculum Integrative program Credts 3
Completion Criteria Major Lecture Types Major
Lecture Methods Korean course Supervising Professors


강의목표, 교재 및 참고문헌, 수업운영방식, 과제물, 성적평가방식으로 구분하여 안내합니다.
Lecture Objectives ? 양자물리 기초, 기체운동학, 방전공학, 절연파괴의 기초에 대한 이론 강의 ? Lectures on the fundmental of quantum physics, gas dynamics, discharge engineering
Textbooks and References
How a Lecture is Conducted
Grading and Score Evaluatios

Weekkly Syllabus

Weekkly Syllabus
Weekkly, 계획으로 구분하여 안내합니다.
1 Week Introduction
2 Week Plasma State
3 Week Quantum Physics(1)
4 Week Quantum Physics(2)
5 Week Discharge(1)
6 Week Discharge(2)
7 Week Charged Particle(1)
8 Week Charged Particle(2)
9 Week Motions of Charged Particles under Uniform field(1)
10 Week Motions of Charged Particles under Uniform field(2)
11 Week Motions of Charged Particles under Uniform field(3)
12 Week Gas Breakdown(1)
13 Week Gas Beakdown(2)
14 Week Gas Breakdown(3)
15 Week Breakdown(4)
16 Week Final Exam