We are studying novel techniques for medical diagnosis, therapy, and biological analysis using light including laser, on the basis of tissue optics, photobiology, and laser engineering. Research interests include less-invasive treatment with infrared lasers, photodynamic therapy for cancer, optical properties of biological tissues, and laser ionization mass spectrometry, and so on. We are developing the human resources which have profound understanding of both engineering and medical fields.
To utilize nuclear reactors more safely and economically, we have been developing more reliable management methods for equipment operation and new types of nuclear reactor by experiment and computer simulation.
We carry on research and education on the safety of nuclear energy, concept of new energy system and so on. At present, main concern is on experimental and numerical studies of hydrodynamics and heat transfer related to liquid metal flow and material behavior loaded by high heat flux. From these studies, we aim to contribute to development of new system of neutron source, fusion reactor and so on. Besides, we study on magnetohydrodynamics (MHD) in order to construct a concept of renewed safety system, heat exchanger and so on.
To achieve a safe chemical processing of spent nuclear fuels and radioactive wastes, we conduct research on chemical behavior of actinides and fission product elements in various electrolyte solutions.
We study radiation physics and engineering for advanced medical and industrial applications. The world’s most intense 14 MeV neutron source facility of Osaka University, OKTAVIAN was constructed by us in 1981. Studies of neutronics (neutron engineering) for Fusion Reactor and Boron Neutron Capture Therapy (BNCT) (new cancer therapy) have been carried out using the OKTAVIAN. Also, we develop new environmental and personal dosimetry methods.