Wavelength-Dependent Solar N2 Fixation into Ammonia and Nitrate in Pure Water

Wavelength-Dependent Solar N2 Fixation into Ammonia and Nitrate in Pure Water

Solar-driven N2 fixation using a photocatalyst in water presents a promising alternative to the traditional Haber-Bosch process in terms of both energy efficiency and environmental concern. At present, the product of solar N2 fixation is either NH4+ or NO3-. Few reports described the simultaneous fo...

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Main Authors: Wenju Ren, Zongwei Mei, Shisheng Zheng, Shunning Li, Yuanmin Zhu, Jiaxin Zheng, Yuan Lin, Haibiao Chen, Meng Gu, Feng Pan
Format: Article
Language:English
Published: American Association for the Advancement of Science 2020-01-01
Series:Research
Online Access:http://dx.doi.org/10.34133/2020/3750314
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spelling doaj-2433bb4140504244be25c4d7053d8b622020-11-25T03:11:24ZengAmerican Association for the Advancement of ScienceResearch2639-52742020-01-01202010.34133/2020/3750314Wavelength-Dependent Solar N2 Fixation into Ammonia and Nitrate in Pure WaterWenju Ren0Wenju Ren1Zongwei Mei2Shisheng Zheng3Shunning Li4Yuanmin Zhu5Yuanmin Zhu6Jiaxin Zheng7Yuan Lin8Haibiao Chen9Meng Gu10Feng Pan11School of Advanced Materials,Peking University,Shenzhen Graduate School,ChinaSchool of Advance Manufacturing Engineering,Chongqing University of Posts and Telecommunications,Chongqing,ChinaSchool of Advanced Materials,Peking University,Shenzhen Graduate School,ChinaSchool of Advanced Materials,Peking University,Shenzhen Graduate School,ChinaSchool of Advanced Materials,Peking University,Shenzhen Graduate School,ChinaDepartment of Materials Science and Engineering,Southern University of Science and Technology,ChinaSUSTech Academy for Advanced Interdisciplinary Studies,Southern University of Science and Technology,ChinaSchool of Advanced Materials,Peking University,Shenzhen Graduate School,ChinaInstitute of Chemistry,Chinese Academy of Sciences,Beijing,ChinaSchool of Advanced Materials,Peking University,Shenzhen Graduate School,ChinaDepartment of Materials Science and Engineering,Southern University of Science and Technology,ChinaSchool of Advanced Materials,Peking University,Shenzhen Graduate School,ChinaSolar-driven N2 fixation using a photocatalyst in water presents a promising alternative to the traditional Haber-Bosch process in terms of both energy efficiency and environmental concern. At present, the product of solar N2 fixation is either NH4+ or NO3-. Few reports described the simultaneous formation of ammonia (NH4+) and nitrate (NO3-) by a photocatalytic reaction and the related mechanism. In this work, we report a strategy to photocatalytically fix nitrogen through simultaneous reduction and oxidation to produce NH4+ and NO3- by W18O49 nanowires in pure water. The underlying mechanism of wavelength-dependent N2 fixation in the presence of surface defects is proposed, with an emphasis on oxygen vacancies that not only facilitate the activation and dissociation of N2 but also improve light absorption and the separation of the photoexcited carriers. Both NH4+ and NO3- can be produced in pure water under a simulated solar light and even till the wavelength reaching 730 nm. The maximum quantum efficiency reaches 9% at 365 nm. Theoretical calculation reveals that disproportionation reaction of the N2 molecule is more energetically favorable than either reduction or oxidation alone. It is worth noting that the molar fraction of NH4+ in the total product (NH4+ plus NO3-) shows an inverted volcano shape from 365 nm to 730 nm. The increased fraction of NO3- from 365 nm to around 427 nm results from the competition between the oxygen evolution reaction (OER) at W sites without oxygen vacancies and the N2 oxidation reaction (NOR) at oxygen vacancy sites, which is driven by the intrinsically delocalized photoexcited holes. From 427 nm to 730 nm, NOR is energetically restricted due to its higher equilibrium potential than that of OER, accompanied by the localized photoexcited holes on oxygen vacancies. Full disproportionation of N2 is achieved within a range of wavelength from ~427 nm to ~515 nm. This work presents a rational strategy to efficiently utilize the photoexcited carriers and optimize the photocatalyst for practical nitrogen fixation.http://dx.doi.org/10.34133/2020/3750314
collection DOAJ
language English
format Article
sources DOAJ
author Wenju Ren
Wenju Ren
Zongwei Mei
Shisheng Zheng
Shunning Li
Yuanmin Zhu
Yuanmin Zhu
Jiaxin Zheng
Yuan Lin
Haibiao Chen
Meng Gu
Feng Pan
spellingShingle Wenju Ren
Wenju Ren
Zongwei Mei
Shisheng Zheng
Shunning Li
Yuanmin Zhu
Yuanmin Zhu
Jiaxin Zheng
Yuan Lin
Haibiao Chen
Meng Gu
Feng Pan
Wavelength-Dependent Solar N2 Fixation into Ammonia and Nitrate in Pure Water
Research
author_facet Wenju Ren
Wenju Ren
Zongwei Mei
Shisheng Zheng
Shunning Li
Yuanmin Zhu
Yuanmin Zhu
Jiaxin Zheng
Yuan Lin
Haibiao Chen
Meng Gu
Feng Pan
author_sort Wenju Ren
title Wavelength-Dependent Solar N2 Fixation into Ammonia and Nitrate in Pure Water
title_short Wavelength-Dependent Solar N2 Fixation into Ammonia and Nitrate in Pure Water
title_full Wavelength-Dependent Solar N2 Fixation into Ammonia and Nitrate in Pure Water
title_fullStr Wavelength-Dependent Solar N2 Fixation into Ammonia and Nitrate in Pure Water
title_full_unstemmed Wavelength-Dependent Solar N2 Fixation into Ammonia and Nitrate in Pure Water
title_sort wavelength-dependent solar n2 fixation into ammonia and nitrate in pure water
publisher American Association for the Advancement of Science
series Research
issn 2639-5274
publishDate 2020-01-01
description Solar-driven N2 fixation using a photocatalyst in water presents a promising alternative to the traditional Haber-Bosch process in terms of both energy efficiency and environmental concern. At present, the product of solar N2 fixation is either NH4+ or NO3-. Few reports described the simultaneous formation of ammonia (NH4+) and nitrate (NO3-) by a photocatalytic reaction and the related mechanism. In this work, we report a strategy to photocatalytically fix nitrogen through simultaneous reduction and oxidation to produce NH4+ and NO3- by W18O49 nanowires in pure water. The underlying mechanism of wavelength-dependent N2 fixation in the presence of surface defects is proposed, with an emphasis on oxygen vacancies that not only facilitate the activation and dissociation of N2 but also improve light absorption and the separation of the photoexcited carriers. Both NH4+ and NO3- can be produced in pure water under a simulated solar light and even till the wavelength reaching 730 nm. The maximum quantum efficiency reaches 9% at 365 nm. Theoretical calculation reveals that disproportionation reaction of the N2 molecule is more energetically favorable than either reduction or oxidation alone. It is worth noting that the molar fraction of NH4+ in the total product (NH4+ plus NO3-) shows an inverted volcano shape from 365 nm to 730 nm. The increased fraction of NO3- from 365 nm to around 427 nm results from the competition between the oxygen evolution reaction (OER) at W sites without oxygen vacancies and the N2 oxidation reaction (NOR) at oxygen vacancy sites, which is driven by the intrinsically delocalized photoexcited holes. From 427 nm to 730 nm, NOR is energetically restricted due to its higher equilibrium potential than that of OER, accompanied by the localized photoexcited holes on oxygen vacancies. Full disproportionation of N2 is achieved within a range of wavelength from ~427 nm to ~515 nm. This work presents a rational strategy to efficiently utilize the photoexcited carriers and optimize the photocatalyst for practical nitrogen fixation.
url http://dx.doi.org/10.34133/2020/3750314
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