高压下轻元素单质的结构相变

压力是物质独立于温度和化学组分的一个重要维度,能够有效改变物质内部原子间的相互作用,诱导形成具有新结构和新性质的高压新相,可以揭示许多常压下不曾有过的新现象和新规律,为制备出常压条件下无法得到的新材料提供了创新性源泉。元素单质在常压下大多具有简单的晶体结构,但在高压下却发生了非常复杂的结构相变,形成了多种新颖的高压相,产生了超导、超硬、金属-绝缘体相变等奇异现象,吸引了科学界的广泛关注。本文针对元素周期表中前12种轻元素单质的高压结构相变、高压相的新奇物理特性及相变产生的物理机制进行了探讨和论述,并对实验和理论高压结构相变的研究方法进行了展望。

关键词： 高压, 结构相变, 晶体结构, 轻元素

Pressure as a very important dimension independent of temperature and chemical compositions, can effectively change the inter-atomic interaction, induce the formation of high pressure structures with new physical properties, reveal new phenomena and physical rules, and fabricate new materials that can not be synthesized under ambient pressure. At ambient conditions, elements usually adopt simple structures; however, application of pressure induces complex phase transitions with the formation of intriguing high pressure phases, some of which possess novel superconductivity and superhard properties, and even experience metal-insulator transitions. These high pressure phase transitions have attracted worldwide attention. This article reviews the structural transitions of the first 12 light elements in the periodical table under pressure, and discusses novel properties of the new high pressure phases and the corresponding phase transition mechanisms. The prospects of the future experimental and theoretical methods for investigation of high pressure phase transitions are presented.

Key words: high pressure, phase transitions, crystal structure, light elements

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高压下轻元素单质的结构相变

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高压下轻元素单质的结构相变

Phase Transitions in Light Elements under Pressure