Low Temperature Melting of Elements under High Pressure and Its Progression in the Periodic Table
スポンサーリンク
概要
- 論文の詳細を見る
Data Obtained and gathered to data regarding melting phenomena in elements and compounds have been both reviewed and summarized in this paper. The result has yielded information concerning a new melting relation for materials, the characteristics of which are described in the following three items. 1) Any solid possesses a maximum melting point at a characteristic applied hydrostatic pressure. 2) At any temperature below the maximum melting point the solid melts at two characteristic pressures. 3) The pressure corresponding to the maximum melting point is lower in a solid composed of elements having a larger mass number; the progression of pressure for the maximum melting point is evident in each group elements in the periodic table.
- 社団法人応用物理学会の論文
- 1968-09-05
著者
-
Inokuti Yukio
Department Of Material Physics Faculty Of Engineering Science Osaka University
-
KAWAI Naoto
Department of Material Physics, Faculty of Engineering Science, Osaka University
-
Kawai Naoto
Department Of Material Physics Faculty Of Engineering Science Osaka University
関連論文
- A Simple High Pressure Apparatus Using Tungsten Carbide Balls
- Low Temperature Melting of Elements under High Pressure and Its Progression in the Periodic Table
- High Pressure Melting of General Compounds, and with Some Physical Models
- Multi-Anvil Apparatus for High Pressure X-Ray Diffraction
- Jupiter's Conductive Molten Core of Moderate Temperature
- Magnetic Properties of Fe_(Ni_Mn_x)_ Alloys under Hydrostatic Pressure
- A Multipurpose High Pressure Microbomb
- Effect of Pressure on the Magnetic Transition Temperature and Electrical Resistance Anomaly in Four Heavy Rare Earth Metals
- Reduction of CrO_3 into CrO_2 and Cr_2O_3 under Very High Pressure and High Temperature
- Preessure Transmission Media at Low Temperatures in Clamped Type High Pressure Bomb
- Magnetic Properties of Manganese Phosphide under Hydrostatic Pressure
- The Effect of Hydrostatic Pressure on the Magnetic Anisotropy of Ferrous and Ferric Ions in Ferrites with Spinel Structure