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混合生物模板光子/光催化纳米结构的光谱工程

Spectral Engineering of Hybrid Biotemplated Photonic/Photocatalytic Nanoarchitectures.

作者信息

Piszter Gábor, Kertész Krisztián, Kovács Dávid, Zámbó Dániel, Baji Zsófia, Illés Levente, Nagy Gergely, Pap József Sándor, Bálint Zsolt, Biró László Péter

机构信息

Institute of Technical Physics and Materials Science, Centre for Energy Research, 29-33 Konkoly Thege Miklós St., 1121 Budapest, Hungary.

Surface Chemistry and Catalysis Department, Institute for Energy Security and Environmental Safety, Centre for Energy Research, 29-33 Konkoly Thege Miklós St., 1121 Budapest, Hungary.

出版信息

Nanomaterials (Basel). 2022 Dec 19;12(24):4490. doi: 10.3390/nano12244490.

DOI:10.3390/nano12244490
PMID:36558345
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC9782751/
Abstract

Solar radiation is a cheap and abundant energy for water remediation, hydrogen generation by water splitting, and CO reduction. Supported photocatalysts have to be tuned to the pollutants to be eliminated. Spectral engineering may be a handy tool to increase the efficiency or the selectivity of these. Photonic nanoarchitectures of biological origin with hierarchical organization from nanometers to centimeters are candidates for such applications. We used the blue wing surface of laboratory-reared male butterflies in combination with atomic layer deposition (ALD) of conformal ZnO coating and octahedral CuO nanoparticles (NP) to explore the possibilities of engineering the optical and catalytic properties of hybrid photonic nanoarchitectures. The samples were characterized by UV-Vis spectroscopy and optical and scanning electron microscopy. Their photocatalytic performance was benchmarked by comparing the initial decomposition rates of rhodamine B. CuO NPs alone or on the butterfly wings, covered by a 5 nm thick layer of ZnO, showed poor performance. Butterfly wings, or ZnO coated butterfly wings with 15 nm ALD layer showed a 3 to 3.5 times enhancement as compared to bare glass. The best performance of almost 4.3 times increase was obtained for the wings conformally coated with 15 nm ZnO, deposited with CuO NPs, followed by conformal coating with an additional 5 nm of ZnO by ALD. This enhanced efficiency is associated with slow light effects on the red edge of the reflectance maximum of the photonic nanoarchitectures and with enhanced carrier separation through the n-type ZnO and the p-type CuO heterojunction. Properly chosen biologic photonic nanoarchitectures in combination with carefully selected photocatalyst(s) can significantly increase the photodegradation of pollutants in water under visible light illumination.

摘要

太阳辐射是一种用于水修复、通过水分解制氢和减少一氧化碳的廉价且丰富的能源。负载型光催化剂必须针对要去除的污染物进行调整。光谱工程可能是提高这些过程效率或选择性的便捷工具。具有从纳米到厘米分级组织的生物源光子纳米结构是此类应用的候选者。我们将实验室饲养的雄性蝴蝶的蓝色翅膀表面与共形ZnO涂层和八面体CuO纳米颗粒(NP)的原子层沉积(ALD)相结合,以探索工程化混合光子纳米结构的光学和催化特性的可能性。通过紫外-可见光谱、光学和扫描电子显微镜对样品进行了表征。通过比较罗丹明B的初始分解速率来衡量它们的光催化性能。单独的CuO NPs或覆盖有5nm厚ZnO层的蝴蝶翅膀上的CuO NPs表现不佳。蝴蝶翅膀或具有15nm ALD层的ZnO涂层蝴蝶翅膀与裸玻璃相比,性能提高了3至3.5倍。对于先沉积CuO NPs、再通过ALD额外共形涂覆5nm ZnO的15nm ZnO共形涂层翅膀,获得了近4.3倍的最佳性能提升。这种提高的效率与光子纳米结构反射率最大值红边处的慢光效应以及通过n型ZnO和p型CuO异质结增强的载流子分离有关。适当选择的生物光子纳米结构与精心挑选的光催化剂相结合,可以在可见光照射下显著提高水中污染物的光降解。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/9833/9782751/7583e48312e9/nanomaterials-12-04490-g010.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/9833/9782751/bc75ea6e790d/nanomaterials-12-04490-g001.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/9833/9782751/6b2820ceeb72/nanomaterials-12-04490-g002.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/9833/9782751/7f08c86bd7d4/nanomaterials-12-04490-g003.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/9833/9782751/4c1fa3fe815f/nanomaterials-12-04490-g004.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/9833/9782751/88995873250c/nanomaterials-12-04490-g005.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/9833/9782751/0cabed68d294/nanomaterials-12-04490-g006.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/9833/9782751/40f232e557eb/nanomaterials-12-04490-g007.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/9833/9782751/baa5111c00bb/nanomaterials-12-04490-g008.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/9833/9782751/bc6459820b31/nanomaterials-12-04490-g009.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/9833/9782751/7583e48312e9/nanomaterials-12-04490-g010.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/9833/9782751/bc75ea6e790d/nanomaterials-12-04490-g001.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/9833/9782751/6b2820ceeb72/nanomaterials-12-04490-g002.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/9833/9782751/7f08c86bd7d4/nanomaterials-12-04490-g003.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/9833/9782751/4c1fa3fe815f/nanomaterials-12-04490-g004.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/9833/9782751/88995873250c/nanomaterials-12-04490-g005.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/9833/9782751/0cabed68d294/nanomaterials-12-04490-g006.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/9833/9782751/40f232e557eb/nanomaterials-12-04490-g007.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/9833/9782751/baa5111c00bb/nanomaterials-12-04490-g008.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/9833/9782751/bc6459820b31/nanomaterials-12-04490-g009.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/9833/9782751/7583e48312e9/nanomaterials-12-04490-g010.jpg

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