Photon-Driven Nitrogen Fixation: Current Progress, Thermodynamic Considerations, and Future Outlook

Medford, Andrew J.; Hatzell, Marta C.

doi:10.1021/acscatal.7b00439

Cited by 470 publications

(451 citation statements)

References 167 publications

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“…[1][2][3][4] Fixing N 2 is the necessaryr eaction for globale cosystem cycle, and the corresponding productiono fN H 3 is in urgent demandw ith wide applications in the agricultural industry,t he pharmaceutical industry,a nd energy storage. [5][6][7][8] In fact, population growth and social development are positivelyc orrelated with NH 3 output.A tp resent, N 2 fixation by naturald initrogenase is far below the standard required owing to sharply increased demands. [9,10] NH 3 is synthesized by the Haber-Bosch approach in very harsh conditions involving of high purity N 2 and H 2 ,w hichi sa ccompanied with the disadvantages of low productivity, release of ag reat deal of greenhouse gases,a nd massive energy consumption.…”

Section: Introductionmentioning

confidence: 99%

Keggin‐Type Polyoxometalate‐Based ZIF‐67 for Enhanced Photocatalytic Nitrogen Fixation

Wang

et al. 2020

ChemSusChem

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The photocatalytic reduction of N2 to NH3 is considered a promising strategy to alleviate human need for accessible nitrogen and environmental pollution, for which developing a photocatalyst is an effective method to complete the transformation of this process. We firstly design a series of highly efficient and stable polyoxometalates (POMs)‐based zeolitic imidazolate framework‐67 (ZIF‐67) photocatalysts for N2 reduction. ZIF‐67 can effectively fix N2 owing to its porosity. Integration of POMs cluster contributes enormous advantages in terms of broadening the absorption spectrum to improve sunlight utilization, enhance the stability of the materials, effectively inhibit the recombination of photo‐generated electron–hole pairs, and reduce charge‐transfer impedance. POMs can absorb light to convert into reduced POMs, which have stronger reducing ability to provide ample electrons to reduce N2. The reduced POMs can recover their oxidation state through contact with an oxidant, which forms a self‐recoverable and recyclable photocatalytic fixing N2 system. The photocatalytic activity enhances with the increasing number V substitutions in the POMs. Satisfactorily, ZIF‐67@K11[PMo4V8O40] (PMo4V8) displays the most significant photocatalytic N2 activity with a NH3 yield of 149.0 μmol L−1 h−1, which is improved by 83.5 % (ZIF‐67) and 78.9 % (PMo4V8). The introduction of POMs provides new insights for the design of high‐performance photocatalyst nanomaterials to reduce N2.

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Section: Introductionmentioning

confidence: 99%

Keggin‐Type Polyoxometalate‐Based ZIF‐67 for Enhanced Photocatalytic Nitrogen Fixation

Wang

et al. 2020

ChemSusChem

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“…[7][8][9][10][11][12][13] Theh igh value-added nitrate products are used as araw ingredient for the production of chemical fertilizer,g unpowder,a nd explo-sives,w hich are of crucial importance to feed the population and defend the national security. [14] Therefore,t he industrial nitrogen fixation to nitrate,b ased on ammonia oxidation, followed by am ulti-step chemical reaction, has been developed and employed, [15,16] but the harsh reaction conditions (i.e.15-25 MPa, 673-873 K, and noble metals) force scientists to seek amore moderate nitrogen fixation approach.…”

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confidence: 99%

Pothole‐rich Ultrathin WO₃ Nanosheets that Trigger N≡N Bond Activation of Nitrogen for Direct Nitrate Photosynthesis

et al. 2018

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Nitrate is ar aw ingredient for the production of fertilizer,g unpowder,a nd explosives.D eveloping an alternative approach to activate the NNbond of naturally abundant nitrogen to form nitrate under ambient conditions will be of importance.Herein, pothole-rich WO 3 was used to catalyse the activation of N Nc ovalent triple bonds for the direct nitrate synthesis at room temperature.T he pothole-rich structure endues the WO 3 nanosheet more dangling bonds and more easily excited high momentum electrons,w hicho vercome the two major bottlenecks in NNb ond activation, that is,p oor binding of N 2 to catalytic materials and the high energy involved in this reaction. The average rate of nitrate production is as high as 1.92 mg g À1 h À1 under ambient conditions,without any sacrificial agent or precious-metal co-catalysts.M ore generally,t he concepts will initiate an ew pathwayf or triggering inert catalytic reactions.

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“…20–40 GJ are needed to produce 1 t of NH 3 . A further problematic aspect that is sometimes overlooked is the very localized character of NH 3 production . H‐B plants are huge facilities with large capacity to decrease production costs.…”

Section: Is There a Real Need For An Alternative Ammonia Production Rmentioning

confidence: 99%

Overcoming Chemical Inertness under Ambient Conditions: A Critical View on Recent Developments in Ammonia Synthesis via Electrochemical N₂ Reduction by Asking Five Questions

Qin

Oschatz

2020

ChemElectroChem

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Ammonia (NH3) synthesis by the electrochemical N2 reduction reaction (NRR) is increasingly studied and proposed as an alternative process to overcome the disadvantages of Haber‐Bosch synthesis by a more energy‐efficient, carbon‐free, delocalized, and sustainable process. An ever‐increasing number of scientists are working on the improvement of the faradaic efficiency (FE) and NH3 production rate by developing novel catalysts, electrolyte concepts, and/or by contributing theoretical studies. The present Minireview provides a critical view on the interplay of different crucial aspects in NRR from the electrolyte, over the mechanism of catalytic activation of N2, to the full electrochemical cell. Five critical questions are asked, discussed, and answered, each coupled with a summary of recent developments in the respective field. This article is not supposed to be a complete summary of recent research about NRR but provides a rather critical personal view on the field. It is the major aim to give an overview over crucial influences on different length scales to shine light on the sweet spots into which room for revolutionary instead of incremental improvements may exist.

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Photon-Driven Nitrogen Fixation: Current Progress, Thermodynamic Considerations, and Future Outlook

Cited by 470 publications

References 167 publications

Keggin‐Type Polyoxometalate‐Based ZIF‐67 for Enhanced Photocatalytic Nitrogen Fixation

Keggin‐Type Polyoxometalate‐Based ZIF‐67 for Enhanced Photocatalytic Nitrogen Fixation

Pothole‐rich Ultrathin WO₃ Nanosheets that Trigger N≡N Bond Activation of Nitrogen for Direct Nitrate Photosynthesis

Overcoming Chemical Inertness under Ambient Conditions: A Critical View on Recent Developments in Ammonia Synthesis via Electrochemical N₂ Reduction by Asking Five Questions

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Photon-Driven Nitrogen Fixation: Current Progress, Thermodynamic Considerations, and Future Outlook

Cited by 470 publications

References 167 publications

Keggin‐Type Polyoxometalate‐Based ZIF‐67 for Enhanced Photocatalytic Nitrogen Fixation

Keggin‐Type Polyoxometalate‐Based ZIF‐67 for Enhanced Photocatalytic Nitrogen Fixation

Pothole‐rich Ultrathin WO3 Nanosheets that Trigger N≡N Bond Activation of Nitrogen for Direct Nitrate Photosynthesis

Overcoming Chemical Inertness under Ambient Conditions: A Critical View on Recent Developments in Ammonia Synthesis via Electrochemical N2 Reduction by Asking Five Questions

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Pothole‐rich Ultrathin WO₃ Nanosheets that Trigger N≡N Bond Activation of Nitrogen for Direct Nitrate Photosynthesis

Overcoming Chemical Inertness under Ambient Conditions: A Critical View on Recent Developments in Ammonia Synthesis via Electrochemical N₂ Reduction by Asking Five Questions