Yu Hulei, Lao Wenxin, Wang Lijuan, Li Kuo, Chen Yue
Department of Mechanical Engineering, The University of Hong Kong, Pokfulam Road, Hong Kong SAR, China.
Center for High Pressure Science and Technology Advanced Research, 10 Dongbeiwang West Road, Haidian, Beijing 100094, China.
Phys Rev Lett. 2017 Mar 31;118(13):137002. doi: 10.1103/PhysRevLett.118.137002. Epub 2017 Mar 28.
Tin-selenium binary compounds are important semiconductors that have attracted much interest for thermoelectric and photovoltaic applications. As tin has a +2 or +4 oxidation state and selenium has an oxidation number of -2, only SnSe and SnSe_{2} have been observed. In this work, we show that the chemical bonding between tin and selenium becomes counterintuitive under pressures. Combining evolutionary algorithms and density functional theory, a novel cubic tin-selenium compound with an unexpected stoichiometry 3∶4 has been predicted and further synthesized in laser-heated diamond anvil cell experiments. Different from the conventional SnSe and SnSe_{2} semiconductors, Sn_{3}Se_{4} is predicted to be metallic and exhibit a superconducting transition at low temperatures. Based on electron density and Bader charge analysis, we show that Sn_{3}Se_{4} has a mixed nature of chemical bonds. The successful synthesis of Sn_{3}Se_{4} paves the way for the discovery of other IV-VI compounds with nonconventional stoichiometries and novel properties.
锡 - 硒二元化合物是重要的半导体,在热电和光伏应用方面引起了广泛关注。由于锡具有 +2 或 +4 的氧化态,而硒的氧化数为 -2,因此仅观察到了 SnSe 和 SnSe₂。在本工作中,我们表明在压力下锡和硒之间的化学键变得违反直觉。结合进化算法和密度泛函理论,预测了一种具有意外化学计量比 3∶4 的新型立方锡 - 硒化合物,并在激光加热金刚石对顶砧实验中进一步合成。与传统的 SnSe 和 SnSe₂ 半导体不同,预测 Sn₃Se₄ 是金属性的,并在低温下表现出超导转变。基于电子密度和巴德电荷分析,我们表明 Sn₃Se₄ 具有混合的化学键性质。Sn₃Se₄ 的成功合成为发现其他具有非常规化学计量比和新颖性质的 IV - VI 化合物铺平了道路。
