Atmospheric‐Pressure Synthesis of 2D Nitrogen‐Rich Tungsten Nitride

Yu, Huimin; Yang, Xin; Xu, Xiao; Chen, Ming; Zhang, Qinghua; Huang, Liang; Wu, Jia-bing; Li, Tianqi; Chen, Shuangming; Li, Song; Gu, Lin; Xia, Bao Yu; Feng, Guang; Li, Jia; Zhou, Jun

doi:10.1002/adma.201805655

Cited by 113 publications

(90 citation statements)

References 32 publications

(35 reference statements)

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“…Figure d shows the Fourier transform (FT) extended X‐ray adsorption fine structure (EXAFS) spectra of the W 2 N 3 and NV‐W 2 N 3 , which are obtained from normalized W L 3 ‐edge curves (Figure S4, Supporting Information). Both samples show a main coordination peak at 2.8 Å which is assigned to WW bonding . However, the intensity of the peak for NV‐W 2 N 3 at 1.8 Å (WN bonding) becomes weaker compared to that of the pristine W 2 N 3 , indicating the decreased WN bonding number.…”

Section: Exafs Curve‐fitting Results (Error Bounds (Accuracies) Were mentioning

confidence: 96%

“…2D material has onefold and fully exposed crystal surface, which is widely used as platform for both theoretical calculations and practical applications in electrocatalysis . In the meantime, many works have shown that 2D materials have surface distortion, which can endow 2D materials and their vacancies with excellent structural stability . Thus, the use of vacancy‐engineered 2D TMNs with single exposed crystal facet and stable vacancy‐site is a feasible way to construct high‐performance NRR catalysts.…”

Section: Exafs Curve‐fitting Results (Error Bounds (Accuracies) Were mentioning

confidence: 99%

“…The synthesis of W 2 N 3 usually needs harsh synthetic conditions (5 GPa and 1480 K) due to the large formation energy of WN bonding. Inspired by Zhou and co‐workers who firstly realized the atmospheric‐pressure synthesis of nitrogen‐rich transition metal nitride by domain matching epitaxy, the sodium ion in Na 2 W 4 O 13 can lead to a facile synthesis of W 2 N 3 with lower formation energy . The as‐prepared 2D W 2 N 3 was then annealed under 5% H 2 /Ar at 500 °C for 3 h to generate nitrogen vacancies on W 2 N 3 surface (the sample is denoted as NV‐W 2 N 3 ).…”

Section: Exafs Curve‐fitting Results (Error Bounds (Accuracies) Were mentioning

confidence: 99%

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Nitrogen Vacancies on 2D Layered W₂N₃: A Stable and Efficient Active Site for Nitrogen Reduction Reaction

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also aggravate the greenhouse effect. [8] Considering the huge energy consumption of this process and the great potential of NH 3 in future energy systems, protonassisted electrocatalytic nitrogen reduction reaction (NRR) under ambient conditions is becoming increasingly important in realizing low-cost artificial nitrogen fixation. [10][11][12] More importantly, the NRR system can be easily integrated with renewable solar and wind energy into an environmentally benign process for NH 3 production. [2,7] Even though various materials have shown NRR activity in aqueous system, their performance are still hindered by the sluggish reaction kinetics and competitive hydrogen evolution reaction (HER) resulting in poor activity and unsatisfactory selectivity. [13][14][15] The active site for electrochemical NRR needs twofold properties: for one thing, it can accept the lone-pair electrons for effective N 2 adsorption and for the other thing it can donate electrons to antibonding orbitals of dinitrogen molecules for the NN triple-bond activation. [9,13,[16][17][18][19][20] From this perspective, vacancy-engineering materials are ideal for practical applications. [9,16,20] By virtue of the electron redistribution and special chemical properties, the vacancies can provide unique active sites for nitrogen adsorption and activation. [9,[21][22][23][24] Up to now, the most common vacancy that has been studied for NRR is oxygen vacancy. For example, oxygen vacancies on transition metal oxides are active for NRR by enhancing the dinitrogen molecule adsorption. [9,25] However, oxygen vacancy can also improve the HER performance of the host matrix, which may result in poor NRR selectivity. [26][27][28] Alternatively, nitrogen vacancies on transition metal nitride (TMN) are considered as an ideal active site for NRR because of its unique vacancy properties for dinitrogen molecule adsorption and poor HER activity. [29,30] However, the nitrogen vacancy on TMN would be deactivated during NRR process thus results in poor stability. [29] In addition, researchers claim that some TMNs are inactive toward NRR in aqueous system, which is in contrary to theoretical calculations. [31] To gain insightful understanding of NRR mechanism, it is necessary to design TMNs with simplex structure and stable surface vacancies for the linkage of theoretical models and real-world catalysts. 2D material has onefold and fully exposed crystal surface, which is widely used as platform for both theoretical calculations and Electrochemical nitrogen reduction reaction (NRR) under ambient conditions provides an avenue to produce carbon-free hydrogen carriers. However, the selectivity and activity of NRR are still hindered by the sluggish reaction kinetics. Nitrogen Vacancies on transition metal nitrides are considered as one of the most ideal active sites for NRR by virtue of their unique vacancy properties such as appropriate adsorption energy to dinitrogen molecule. However, their catalytic performance is usually limited by the unstable feature. Herein, a new ...

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Section: Exafs Curve‐fitting Results (Error Bounds (Accuracies) Were mentioning

confidence: 96%

Section: Exafs Curve‐fitting Results (Error Bounds (Accuracies) Were mentioning

confidence: 99%

Section: Exafs Curve‐fitting Results (Error Bounds (Accuracies) Were mentioning

confidence: 99%

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Nitrogen Vacancies on 2D Layered W₂N₃: A Stable and Efficient Active Site for Nitrogen Reduction Reaction

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“…These effective LiPSs absorbents include polar metal oxides, such as MnO 2 , TiO 2 , Nb 2 O 5 , etc. Transition metal dichalcoginde (TMDs) are also reported with excellent performance when retarding the LiPSs shuttle . Very recently, Zhou et al reported the synthesis of 2D nitrogen‐rich tungsten nitride through the atmospheric‐pressure method; The formation energy of 2D hexagonal‐W 2 N 3 (h‐W 2 N 3 ) flakes are dramatically decreased owing to the strong interaction and domain matching epitaxy between KCl and h‐W 2 N 3 .…”

Section: Methodsmentioning

confidence: 99%

A Robust, Freestanding MXene‐Sulfur Conductive Paper for Long‐Lifetime Li–S Batteries

Tang

Pan

et al. 2019

Adv Funct Materials

225

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Freestanding, robust electrodes with high capacity and long lifetime are of critical importance to the development of advanced lithium-sulfur (Li-S) batteries for next-generation electronics, whose potential applications are greatly limited by the lithium polysulfide (LiPS) shuttle effect. Solutions to this issue have mostly focused on the design of cathode hosts with a polar, sulfurphilic, conductive network, or the introduction of an extra layer to suppress LiPS shuttling, which either results in complex fabrication procedures or compromises the mechanical flexibility of the device. A robust Ti 3 C 2 T x /S conductive paper combining the excellent conductivity, mechanical strength, and unique chemisorption of LiPSs from MXene nanosheets is reported. Importantly, repeated cycling initiates the in situ formation of a thick sulfate complex layer on the MXene surface, which acts as a protective membrane, effectively suppressing the shuttling of LiPSs and improving the utilization of sulfur. Consequently, the Ti 3 C 2 T x /S paper exhibits a high capacity and an ultralow capacity decay rate of 0.014% after 1500 cycles, the lowest value reported for Li-S batteries to date. A robust prototype pouch cell and full cell of Ti 3 C 2 T x /S paper // lithium foil and prelithiated germanium are also demonstrated. The preliminary results show that Ti 3 C 2 T x /S paper holds great promise for future flexible and wearable electronics.

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“…[5] However, the development of ultrathin 2D magnetic materials, potentially important building blocks for spintronics, is still at its initial stage and only a handful of materials have the physics in ultrathin and bulk magnetic materials, and for practical applications. [18,19] This provides a viable route to obtain ultrathin flakes of a TMN with roomtemperature magnetism. This is a common issue in ultrathin 2D or 2D-like TMNs, and because of this, only a few of these materials have been reported, such as Ti 4 N 3 , [16] Mo 2 N, and V 2 N MXene, [17] MoN, [18] and W 2 N. [18] Recently, a high-yield salt-templating method for the synthesis of atomically thin TMNs by ammoniating their metal oxide counterparts was demonstrated.…”

Section: Introductionmentioning

confidence: 99%

Scalable Synthesis of Ultrathin Mn₃N₂ Exhibiting Room‐Temperature Antiferromagnetism

Urbankowski

Hantanasirisakul

et al. 2019

Adv Funct Materials

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Ultrathin and 2D magnetic materials have attracted a great deal of attention recently due to their potential applications in spintronics. Only a handful of stable ultrathin magnetic materials have been reported, but their high-yield synthesis remains a challenge. Transition metal (e.g., manganese) nitrides are attractive candidates for spintronics due to their predicted high magnetic transition temperatures. Here, a lattice matching synthesis of ultrathin Mn 3 N 2 is employed. Taking advantage of the lattice match between a KCl salt template and Mn 3 N 2 , this method yields the first ultrathin magnetic metal nitride via a solution-based route. Mn 3 N 2 flakes show intrinsic magnetic behavior even at 300 K, enabling potential room-temperature applications. This synthesis procedure offers an approach to the discovery of other ultrathin or 2D metal nitrides.

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Atmospheric‐Pressure Synthesis of 2D Nitrogen‐Rich Tungsten Nitride

Cited by 113 publications

References 32 publications

Nitrogen Vacancies on 2D Layered W₂N₃: A Stable and Efficient Active Site for Nitrogen Reduction Reaction

Nitrogen Vacancies on 2D Layered W₂N₃: A Stable and Efficient Active Site for Nitrogen Reduction Reaction

A Robust, Freestanding MXene‐Sulfur Conductive Paper for Long‐Lifetime Li–S Batteries

Scalable Synthesis of Ultrathin Mn₃N₂ Exhibiting Room‐Temperature Antiferromagnetism

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Atmospheric‐Pressure Synthesis of 2D Nitrogen‐Rich Tungsten Nitride

Cited by 113 publications

References 32 publications

Nitrogen Vacancies on 2D Layered W2N3: A Stable and Efficient Active Site for Nitrogen Reduction Reaction

Nitrogen Vacancies on 2D Layered W2N3: A Stable and Efficient Active Site for Nitrogen Reduction Reaction

A Robust, Freestanding MXene‐Sulfur Conductive Paper for Long‐Lifetime Li–S Batteries

Scalable Synthesis of Ultrathin Mn3N2 Exhibiting Room‐Temperature Antiferromagnetism

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Nitrogen Vacancies on 2D Layered W₂N₃: A Stable and Efficient Active Site for Nitrogen Reduction Reaction

Nitrogen Vacancies on 2D Layered W₂N₃: A Stable and Efficient Active Site for Nitrogen Reduction Reaction

Scalable Synthesis of Ultrathin Mn₃N₂ Exhibiting Room‐Temperature Antiferromagnetism