论文部分内容阅读
日本九州工业大学和九州大学组成的研究团队,在实验中通过压力和摩擦等加工方法,赋与剪切应变,使铼超导转变温度(电阻为零的温度)提高两倍。由于剪切应变,使单位晶格增大,电子状态发生变化,同电阻变零有关的电子格子相互作用(负电荷电子从正电荷电子间穿过),两者相互影响,加剧了电子格子的相互作用,这种现象通过电子状态计算得到查明。实验结果表明,高压应变是各向同性的,而砂纸摩擦的应变是
Japan Kyushu University of Technology and Kyushu University research team, in the experiment by pressure and friction and other processing methods, given Shear strain, rhenium superconducting transition temperature (resistance temperature of zero) tripled. Due to shear strain, the unit lattice increases, the electronic state changes, with the zero resistance-related electronic lattice interaction (negative charge electrons from the positive charge between the electrons through), both exacerbate the electronic lattice Interaction, this phenomenon is calculated through the electronic state. Experimental results show that the high-pressure strain is isotropic, while the strain of the abrasive paper is