钻石
材料科学
复合材料
极限抗拉强度
弹性(物理)
千分尺
纳米技术
光学
物理
作者
Chaoqun Dang,Jyh‐Pin Chou,Bing Dai,C.C. Chou,Yang Yang,Rong Fan,Weitong Lin,Fanling Meng,Alice Hu,Jiaqi Zhu,Jiecai Han,Andrew M. Minor,Ju Li,Yang Lü
出处
期刊:Science
[American Association for the Advancement of Science]
日期:2020-12-31
卷期号:371 (6524): 76-78
被引量:209
标识
DOI:10.1126/science.abc4174
摘要
Diamond is not only the hardest material in nature, but is also an extreme electronic material with an ultrawide bandgap, exceptional carrier mobilities, and thermal conductivity. Straining diamond can push such extreme figures of merit for device applications. We microfabricated single-crystalline diamond bridge structures with ~1 micrometer length by ~100 nanometer width and achieved sample-wide uniform elastic strains under uniaxial tensile loading along the [100], [101], and [111] directions at room temperature. We also demonstrated deep elastic straining of diamond microbridge arrays. The ultralarge, highly controllable elastic strains can fundamentally change the bulk band structures of diamond, including a substantial calculated bandgap reduction as much as ~2 electron volts. Our demonstration highlights the immense application potential of deep elastic strain engineering for photonics, electronics, and quantum information technologies.
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