The university has one of the largest student populations in the Shikoku region. After Japan’s defeat in World War II, Aidai was established in May 1949 among many other national universities by the Japanese government during the reformation of the education system.
The university originally had three Faculties : Humanities and Science, Education, and Engineering; which were consolidated from Matsuyama National High School (established 1919), Ehime Prefectural Teachers School (1876), Ehime Prefectural Youth Teachers School (1927), and Ehime Prefectural Niihama Technical School (1939). Today, the university has six faculties and five graduate schools.
Integration of a Hime Diamond into the Device Simplifies Measurement of Electrical Resistance under Ultra-High Pressure.
Researchers of National Institute of Materials Science and Ehime University, Japan, developed a new diamond anvil cell by micro-fabricating a superconducting diamond, which conducts electricity like metal and serves as electrodes, on the world’s hardest and chip-proof nano-polycrystalline diamond.
A research group led by Yoshihiko Takano, a leader of the Nano Frontier Superconducting Materials Group, Environment and Energy Materials Division, NIMS, and another research group led by Tetsuo Irifune, a director of the Geodynamics Research Center (GRC), Ehime University, jointly developed a new diamond anvil cell (DAC) by micro-fabricating a superconducting diamond, which conducts electricity like metal and serves as electrodes, on the world’s hardest and chip-proof nano-polycrystalline diamond (Hime diamond). As a result, the conventional practice of skillfully attaching four electrodes to a small sample (of several dozen microns) was eliminated, and thus electrical resistance measurements under ultra-high pressure have become much easier. Furthermore, because diamond electrodes can be used repeatedly, physical property measurements have dramatically improved in terms of work and economic efficiencies.
As shown in the right diagram in Figure 1, a typical DAC is a device to generate high pressure by pressing curettes of paired diamond anvils on each other. To increase the pressure generated by the device, it is necessary to make the areas of the curettes smaller. Specifically, to generate ultra-high pressure (several hundreds of thousands of atmospheric pressure), curettes need to be about 400 microns in diameter.
Operation of such a device would be very difficult due to the requirement that the sizes of the samples to be studied need to be as small as about 100 microns. To generate a million atmospheric pressure or higher, the sizes of the samples need to be even smaller, making it extremely challenging to manually attach electrodes to the samples.
Accordingly, research group micro-fabricated superconducting diamond electrodes on the top of the anvil using the electron-beam lithography method. As it is convenient to use a plate-shaped diamond for the fabrication of electrodes using lithography, they combined a plate-shaped diamond and another diamond with a curette to form a diamond anvil cell with its shape as shown in the left diagram in Figure 1.