孔径可调的多孔氮化硼

Porous Boron Nitride with Tunable Pore Size.

作者信息

Dai Jun, Wu Xiaojun, Yang Jinlong, Zeng Xiao Cheng

机构信息

†Department of Chemistry and Nebraska Center for Materials and Nanoscience, University of Nebraska-Lincoln, 536 Hamilton Hall, Lincoln, Nebraska 68588, United States.

‡CAS Key Lab of Materials for Energy Conversion, Department of Materials Science and Engineering and Hefei National Lab for Physical Science at Microscale, University of Science and Technology of China, Jinzhai Road 96, Hefei, Anhui 230026, China.

出版信息

J Phys Chem Lett. 2014 Jan 16;5(2):393-8. doi: 10.1021/jz4026535. Epub 2014 Jan 7.

DOI:10.1021/jz4026535

PMID:26270717

Abstract

On the basis of a global structural search and first-principles calculations, we predict two types of porous boron-nitride (BN) networks that can be built up with zigzag BN nanoribbons (BNNRs). The BNNRs are either directly connected with puckered B (N) atoms at the edge (type I) or connected with sp(3)-bonded BN chains (type II). Besides mechanical stability, these materials are predicted to be thermally stable at 1000 K. The porous BN materials entail large surface areas, ranging from 2800 to 4800 m(2)/g. In particular, type-II BN material with relatively large pores is highly favorable for hydrogen storage because the computed hydrogen adsorption energy (-0.18 eV) is very close to the optimal adsorption energy (-0.15 eV) suggested for reversible hydrogen storage at room temperature. Moreover, the type-II materials are semiconductors with width-dependent direct bandgaps, rendering the type-II BN materials promising not only for hydrogen storage but also for optoelectronic and photonic applications.

摘要

基于全局结构搜索和第一性原理计算，我们预测了两种类型的多孔硼氮化物（BN）网络，它们可以由锯齿状硼氮纳米带（BNNRs）构建而成。这些BNNRs要么在边缘处与褶皱的B（N）原子直接相连（I型），要么与sp(3)键合的BN链相连（II型）。除了机械稳定性外，这些材料预计在1000 K时具有热稳定性。多孔BN材料具有较大的表面积，范围为2800至4800 m²/g。特别是，具有相对较大孔隙的II型BN材料非常有利于储氢，因为计算得到的氢吸附能（-0.18 eV）非常接近室温下可逆储氢建议的最佳吸附能（-0.15 eV）。此外，II型材料是具有宽度依赖直接带隙的半导体，这使得II型BN材料不仅在储氢方面，而且在光电子和光子应用方面都很有前景。

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孔径可调的多孔氮化硼

Porous Boron Nitride with Tunable Pore Size.

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