Laboratory introduction
Astronomy Lab.
- Makoto WATANABE
Our group is studying the internal structure, physical condition, formation, and evolution of the active galactic nuclei, and also studying the adaptive optics in astronomy.
Elementary Particle Physics Group
- Keiko NAGAO
Theoretical particle physics and particle cosmology, especially dark matter, collider physics and origin of matter-antimatter asymmetry.
Condensed Matter Theory Lab.
- Yoshiki IMAI
Theoretical study of the topological materials and strongly correlated electron systems.
Condensed Matter NMR Group
- Tetsuro KUBO
We study various phenomena in condensed matter, especially magnetism, superconductivity, and anomalous metallic states using NMR spectroscopy.
Functional Molecular Solid Lab.
- Kaoru YAMAMOTO
Exploring potential application of unconventional ferroelectric organics using various micro-spectroscope techniques
Semiconductor Physics Lab.
- Minoru YONETA
Study of the fundamental properties of semiconductor compounds with a slight influence to the environment.
Coherent Wave Application Lab.
- Hiroki ISHIDA
Applications of coherent waves. In-vivo blood flow imaging by using laser light. Wireless power transmissions by magnetic resonance.
Geophysics Lab.
- Shin TOYODA
Development and applications of dating methods based on solid state physics, such as electron spin resonance, and radiation effects are investigated, together with radiation dosimetry.
Medical Equipment Application Lab.
- Masahiro OZAKI
We propose a new monitoring system of urea in a waste dialysate by detecting chemiluminescence (CL).
Pathology and Medical Biophysics Lab.
- Teruyuki KAWABATA
Pathological and Biophysical study of iron-induced oxidative stress and diseases.
Advanced Clinical Engineering Lab.
- Jun’ya HORI
Study of: 1) Safety management of medical electrical equipment. 2) Physical properties of Fine-Bubbles (Micro-bubbles, Ultra-Fine-Bubbles), and its application.
Course
Advanced Nuclear Physics
This course covers the basis of quantum field theory and several applications, including Bose-Einstein condensation, superconductivity, and others.
Quantum Radiation Physics
In this lecture, electron excitation, charge-changing and related phenomena in matter induced by swift charge particles, are presented. The physical world will be studied on the basis of mechanics, electrodynamics and quantum mechanics using controlled ion beams.
Advanced Semiconductor Physics
This lecture is an introduction to semiconductor physics. The fundamental character of lattice-defect in a semiconductor, and the thin-film growth technique of semiconductor are presented.
Physical Metallurgy
In this lecture, deformation and fracture behavior of real metal materials as well as defect-free, ideal metal crystals are discussed from the viewpoints of microstructure and chemical composition.
Molecular Solid State Physics
Fundamental solid state physics are discussed to understand the physical properties of functional organic solids. Beginning with the basic quantum mechanics, we proceed to learn the features of the electron in a periodic potential, and eventually apply the knowledge to the explanation of electric and optical properties.
Advanced Planetary Science
Meteorites, cosmic dusts and planets in our solar system, and the detection of extrasolar planets are covered. Recent papers related to solar planetary sciences and extrasolar planets will be read and discussed.
Solid State Geophysics
Physics-based radiation effects will be studied, hence the dating methods based on solid state physics, and their application to earth sciences and to archaeology.
Optical and Infrared Astronomy
The purpose of this lecture is to understand the fundamentals of the radiative processes of visible and infrared light in astrophysics, and the observational quantities, methods, and technologies in the optical and infrared astronomy.
Quantum Theory of Condensed Matter
This lecture course provides the theory of a phenomenon of superconductivity. The aim of this lecture is to understand Ginzburg-Landau (GL) theory as a phenomenology and the Bardeen-Cooper-Schrieffer (BCS) theory as a microscopic one.
Advanced topics in coherent waves
The purpose of this lecture is to understand the mathematical expressions of wave motion. In particular we focus on coherent waves. Through this lecture, you will understand the coherency of wave motion and then learn about these applied techniques.
Electrophysiology
In the first part of this lecture, we will study the basic mechanism of the neuron which generates and transmits electrical signals, then about the neural networks of the human nervous system. EEG and MEG will be studied as an introduction to clinical applications of electrophysiology.
Pathology and Medical Biophysics
We study the basics of oxidative stress and cell injuries through Biophysics. We will focus on iron- and copper-induced oxidative stress rich in the human body. To help with the investigation, electron spin resonance which is very useful for the pathological and medical studies will be used.
Mathematical Physiology
In this lecture, we will look at the physiological phenomena such as respiration and circulation from the viewpoint of physics using dynamics, fluid mechanics, electromagnetism, and thermodynamics.
Blood Purification Studies
In this course, we provide knowledge about the process of hemodialysis and its future image that has been conducted by trial and error for more than 60 years. We will study the process of hemodialysis and how it has changed by trial and error over the past 60 years and how it may change in the future.