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硼掺杂(氮缺陷)和氮掺杂(硼缺陷)的硼氮纳米管光催化剂用于净化水体中污染物的潜力。

The potentials of boron-doped (nitrogen deficient) and nitrogen-doped (boron deficient) BNNT photocatalysts for decontamination of pollutants from water bodies.

作者信息

Itas Yahaya Saadu, Isah Kamaluddeen Abubakar, Nuhu Awwal Hussain, Razali Razif, Tata Salisu, K A Naseer, Idris Abubakr M, Ullah Md Habib, Khandaker Mayeen Uddin

机构信息

Department of Physics, Bauchi State University, Gadau PMB 65 Gadau Bauchi Nigeria

Department of Physics Faculty of Science, Universiti Teknologi Malaysia Malaysia.

出版信息

RSC Adv. 2023 Aug 9;13(34):23659-23668. doi: 10.1039/d3ra03838f. eCollection 2023 Aug 4.

DOI:10.1039/d3ra03838f
PMID:37564254
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC10410231/
Abstract

This work investigates the structural, elastic, electronic, and photoabsorption properties of boron- (N-deficient) and nitrogen- (B-deficient) doped single-walled boron nitride nanotube (SWBNNT) for photocatalytic applications for the first time. All calculations of the optimized systems were performed with DFT quantum simulation codes. The results of the structural analysis showed that SWBNNT is stable to both B and N dopants. It was also observed that the photodecomposition activity of the B-doped nanotube improved significantly under the condition of slight compressive stress, while it decreased for the N-doped nanotube. Therefore, N-doped SWBNNT showed poor performance under external pressure. Both B and N-doped systems could narrow the wide band gap of SWBNNT to the photocatalytic region below 3 eV, therefore this material can be used as photocatalysts in water splitting for hydrogen evolution, dye degradation, wastewater treatment, Analysis of the optical properties revealed that B-doped SWBNNT absorbs more photons in the visible range than the N-doped SWBNNT and can therefore be considered as a more efficient photocatalyst. In addition, it was found that all doped nanotubes are anisotropic since the absorption in one direction of nanotube axes is worse than the other.

摘要

本研究首次探讨了硼(氮缺陷)和氮(硼缺陷)掺杂的单壁氮化硼纳米管(SWBNNT)在光催化应用中的结构、弹性、电子和光吸收特性。所有优化系统的计算均使用DFT量子模拟代码进行。结构分析结果表明,SWBNNT对硼和氮掺杂剂均具有稳定性。还观察到,在轻微压缩应力条件下,硼掺杂纳米管的光分解活性显著提高,而氮掺杂纳米管的光分解活性则降低。因此,氮掺杂的SWBNNT在外部压力下表现不佳。硼和氮掺杂系统均可将SWBNNT的宽带隙缩小至3 eV以下的光催化区域,因此该材料可用于光催化析氢、染料降解、废水处理等水分解反应。光学性质分析表明,硼掺杂的SWBNNT在可见光范围内比氮掺杂的SWBNNT吸收更多光子,因此可被视为更高效的光催化剂。此外,发现所有掺杂纳米管均具有各向异性,因为纳米管轴一个方向上的吸收比另一个方向差。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/b8d5/10410231/ff709bfb9890/d3ra03838f-f8.jpg
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