Course title
1M983400,7M4700001
Advanced Quantum-Beam Applications

 NISHIKAWA Hiroyuki
Course content
The word “quantum” refers to discrete units of matter and energy, such as electron, ions, photons, and neutrons, etc. Our daily lives are surrounded by the quanta in nature, such as photons from the sun and energetic ions in plasma of auroras. If we can produce, extract, and control the quanta as a beam, we can utilize the quantum beam for analysis, fabrication, and even for medical applications.

In this lecture, various techniques for quantum beam applications will be introduced to understand how the advanced technologies have been developed for advanced science, manufacturing industry, and medical applications.
Purpose of class
Quantum beam technologies have been indispensable to our daily things and lives. The purpose of the class is to understand how the advanced technologies have been developed for advanced science, manufacturing industry, and medical applications. Participants of this class can gain basic knowledge to understand and explore the rapidly growing technology areas.
Goals and objectives
  1. Understanding the basic properties of particles, such as photons and charged particles
  2. Understanding the methods to produce and control quantum beams
  3. To demonstrate the knowledge on the techniques used in quantum beam applications
Relationship between 'Goals and Objectives' and 'Course Outcomes'

 Reports Presentation Total.
1. 10% 20% 30%
2. 10% 20% 30%
3. 20% 20% 40%
Total. 40% 60% -
Language
Japanese(English accepted)
Class schedule

 Class schedule HW assignments (Including preparation and review of the class.) Amount of Time Required
1. Guidance and introduction to the course. Introduction to quantum beam applications. Check out the word "quantum" and review texts for introductory quantum mechanics learned in the undergraduate program. 190minutes
2. Photons and charged particles. Wave particle duality. Reading materials assigned for the next week. 190minutes
3. Light beam 1, Light sources (lasers, plasma) Reading materials assigned for the next week. 190minutes
4. Light beam 2, Basic optical system Reading materials assigned for the next week. 190minutes
5. Light beam 3, Optics for beam steering Reading materials assigned for the next week. 190minutes
6. Charged particle beam 1, Electron and ion source, beam transport Reading materials assigned for the next week. 190minutes
7. Charged particle beam 2, Electron and ion beam optics Reading materials assigned for the next week. 190minutes
8. Interaction of quantum beams with matters 1, Photons and matters. Reading materials assigned for the next week. 190minutes
9. Interaction of quantum beams with matters 2, Electrons and matters Reading materials assigned for the next week. 190minutes
10. Interaction of quantum beams with matters 3, Ions with matters Reading materials assigned for the next week. 190minutes
11. Quantum beam applications 1, analysis and fabrication using light beam Reading materials assigned for the next week. 190minutes
12. Quantum beam applications 2, analysis and fabrication using electron beam Reading materials assigned for the next week. 190minutes
13. Quantum beam applications 3, analysis and fabrication using ion beam Reading materials assigned for the next week. 190minutes
14. Current topics on quantum beam applications Reading materials assigned for the next week. 190minutes
Total. - - 2660minutes
Evaluation method and criteria
Students will be comprehensively evaluated based on reports 40% and presentations relating to electrical materials 60%.
Total scores of more than 60% are required to pass the course.

To get more than 60% of the total scores, participants must demonstrate the ability to understand and explain
1) the basic properties of various quantum beams such as photons, charged particles, etc.,
2) the technical issues with producing and controlling the quantum beams,
3) their interactions with materials in terms of applications in various scientific and industry areas
Feedback on exams, assignments, etc.
ways of feedback specific contents about "Other"
Feedback in the class
Textbooks and reference materials
Selected papers from the Journals such as, Nature, Science, Journal of Applied Physics, Applied Physics Letters, Physical Review B.
Prerequisites
Basic knowledge of electromagnetics, quantum mechanics, solid state physics, materials science, electrical and electronic materials.
Office hours and How to contact professors for questions
  • Tuesday, 12:30-13:10
    email: nishi@shibaura-it.ac.jp
Regionally-oriented
Non-regionally-oriented course
Development of social and professional independence
  • Course that cultivates an ability for utilizing knowledge
  • Course that cultivates a basic self-management skills
  • Course that cultivates a basic problem-solving skills
Active-learning course
About half of the classes are interactive
Course by professor with work experience
Work experience Work experience and relevance to the course content if applicable
N/A N/A
Education related SDGs:the Sustainable Development Goals
  • 9.INDUSTRY, INNOVATION AND INFRASTRUCTURE
Last modified : Tue Aug 27 13:59:04 JST 2024