Nuclear Engineering
Graduate MajorCurriculum
An educational curriculum for
developing globally successful individuals who
contribute to society
In the Graduate Major in Nuclear Engineering, related courses are organized into categories to provide systematic, specialized learning according to students' level of learning and attainment.
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Entrance
Examination
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- Applicants must pass an entrance examination to advance from an undergraduate major to a master's program.
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Master's Program
( 2 Years )*1
- 400-Level and 500-Level Courses
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The curriculum is structured to allow students to acquire advanced specialized knowledge of nuclear engineering, broad vision and education, and a strong sense of ethics and responsibility based on the systematic or comprehensive knowledge of science and engineering learned in the Undergraduate Program. It also enables students to acquire more advanced specialized knowledge, logical dialogue skills, writing skills, practical problem-solving ability, and creativity through Research Seminars and master's thesis research.
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- Nuclear Reactor Engineering
- Nuclear reactors are large systems utilizing various technologies. In this course group, students learn basic engineering necessary for systematically and comprehensively understanding reactor systems.
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- Nuclear Reactor Decommissioning Engineering
- Students learn basic engineering necessary for safely decommissioning the Fukushima Daiichi Nuclear Power Station and the increasing number of nuclear reactors that have reached the end of their lifespan.
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- Nuclear Fuel Cycle Engineering
- Students learn basic engineering necessary for producing and supplying fuel, and for safely disposing of spent fuel, which is essential for operating nuclear reactors.
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- Radiation Biology and Medicine
- Accurate knowledge related to the impact of radiation on the human body and other living things is essential for the safe utilization of nuclear energy. In this course group, students study the impact of radiation on living things and its medical applications.
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- Nuclear Fusion / Accelerator Engineering
- Nuclear fusion is expected to resolve future energy problems. In addition, accelerators have become more widely used in the fields of medicine and natural science. In this course group, students learn basic engineering related to nuclear fusion reactors and accelerators.
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- Basic Nuclear Engineering
- Successful researchers and leaders in nuclear power must have strong ethics and a sense of social responsibility, and have knowledge of various safety regulations. In this course group, students work to meet these requirements.
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- Wide and Advanced Nuclear Engineering
- In order to effectively promote the use of nuclear power and radiation, not only is it essential to understand related engineering knowledge, it is also necessary to understand a wide range of disciplines, the relationship between resources/nature and energy, and the relationship between safety/security and society. In this course group, students acquire the latest knowledge in these fields.
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- Internships
- In order to acquire genuinely practical abilities after graduating, students can experience internships, etc., and consider the meaning and application of what they have learned and contemplate their future goals. In this course group, there are internships related to decommissioning engineering in Japan and overseas.
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- Research Seminars
- Research Seminars and literature reviews are conducted to support students in their master's thesis research.
*1Indicates the standard model where the master's program is completed in two years.
<Department of Mechanical Engineering>
<Department of Electrical and Electronic Engineering>
<Department of Materials Science and Engineering>
<Department of Chemical Science and Engineering>
<Department of Transdisciplinary Science and Engineering>
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Completion
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- Advancement Assessment
- Applicants must pass an advancement
assessment to advance from a master's program to a doctoral program.
Other Universities' Graduates and Working Adults
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- Entrance Examination
- Applicants must pass an entrance
assessment to advance from another university to a doctoral program.
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Doctoral Program
( 3 Years )*2
- 600-Level Courses
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The curriculum is designed to allow students to polish what they have learned in the Master's Program, including advanced specialized knowledge of nuclear engineering, broad vision and education, a sense of ethics and social responsibility, logical dialogue skills, writing skills, practical problem-solving skills, and creativity. Furthermore, it enables students to acquire the abilities to discover problems and research them, to create new knowledge, to disseminate, to pioneer and lead new fields, and to develop leadership with which they can play an active role in international society.
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- Nuclear Reactor Engineering
- Knowledge of nuclear reactor engineering acquired in the Master's Program is more deeply and practically studied, along with cutting-edge research.
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- Nuclear Fuel Cycle Engineering
- Knowledge of nuclear fuel cycle engineering acquired in the Master's Program is more deeply and practically studied including cutting-edge research.
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- Nuclear Fusion / Accelerator Engineering
- Knowledge of nuclear fusion / accelerator engineering acquired in the Master's Program is more deeply and practically studied, along with cutting-edge research.
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- Dispatch Project
- By participating in research activities at research institutes, companies, and overseas universities outside Tokyo Tech, more advanced knowledge and experience are acquired.
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- Research Seminars
- Research Seminars and literature reviews are conducted to support students in their doctoral thesis research.
*2Indicates the standard model where the Doctoral Program is completed in three years.
<Department of Mechanical Engineering>
<Department of Electrical and Electronic Engineering>
<Department of Materials Science and Engineering>
<Department of Chemical Science and Engineering>
<Department of Transdisciplinary Science and Engineering>
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Completion
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