Exploring hexagonal boron nitride as an efficient visible light induced catalyst for the remediation of recalcitrant antibiotic from aqueous media

Environmental Research and Technology Pub Date : 2022-10-11 DOI:10.35208/ert.1144689

Zeynep Balta, Esra Bilgin Simsek

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Abstract

In this study, novel non-metallic hexagonal boron nitride (h-BN) whiskers were fabricated by using polymeric precursor method and, the photocatalytic degradation performance was measured towards tetracycline antibiotic under visible-light-illumination. The morphological, physical, and optical features of the catalyst were identified by several characterization analyses. The characteristic peaks associated with hexagonal phase of boron nitride were determined and high crystallinity of h-BN was confirmed by XRD analysis. Typical boron and nitrogen bonding peaks were detected in FTIR spectrum. Brunauer−Emmet−Teller specific surface area of the boron nitride catalyst was calculated as 1019 m2/g which was relatively high, supplying abundant active regions to interact with the target pollutant. In photocatalytic degradation experiments, 91.9% of tetracycline decomposition was achieved within 180 min while the adsorptive removal was calculated as 20%. The outstanding catalytic activity of h-BN catalyst was attributed to the high surface area and negatively charged groups on the surface which captured the photo-induced holes and inhibited the recombination rate of charge carriers. These findings highlight the potential application of h-BN in the field of photocatalytic processes.

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探索六方氮化硼作为一种可见光诱导催化剂用于水中顽固抗生素的修复

本研究采用聚合前驱体法制备了新型非金属六方氮化硼(h-BN)晶须，并在可见光照射下测定了其对四环素类抗生素的光催化降解性能。催化剂的形态、物理和光学特征通过一些表征分析得到了鉴定。测定了氮化硼六方相的特征峰，并通过XRD分析证实了h-BN的高结晶度。在红外光谱中检测到典型的硼和氮键峰。计算得到氮化硼催化剂的Brunauer - Emmet - Teller比表面积为1019 m2/g，相对较高，提供了丰富的活性区域与目标污染物相互作用。在光催化降解实验中，180 min内四环素的分解率为91.9%，吸附去除率为20%。h-BN催化剂具有优异的催化活性是因为其表面的高表面积和负电荷基团捕获了光诱导空穴，抑制了载流子的重组速率。这些发现突出了氢氮化硼在光催化过程领域的潜在应用。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Environmental Research and Technology

CiteScore

0.90

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0.00%

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