Metal–Organophosphine Framework‐Derived N,P‐Codoped Carbon‐Confined Cu<sub>3</sub>P Nanopaticles for Superb Na‐Ion Storage

Kong, Minhong; Song, Huaihe; Zhou, Ji

doi:10.1002/aenm.201801489

Cited by 96 publications

(80 citation statements)

References 51 publications

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“…[42] For the highresolution N 1s XPS spectra, three peaks at 399.3, 400.2, and 401.5 eV correspond to the BE of pyridinic N, pyrrodic N, and graphitic N, respectively, which also confirm the successful formation of N-doped carbon. [43] Note that XPS spectra indicate that N and P atoms are not bonded to form any PN species. [44] According to XPS data, CoP/NPC/TF consists of Co (19.80%), P (22.15%), C (39.52%), N (6.31%), and O (12.22%) (Table S1, Supporting Information).…”

Section: Resultsmentioning

confidence: 99%

Vertical CoP Nanoarray Wrapped by N,P‐Doped Carbon for Hydrogen Evolution Reaction in Both Acidic and Alkaline Conditions

Huang

et al. 2019

Advanced Energy Materials

304

139

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commercial application is significantly restricted due to the paucity and preciousness of Pt. Therefore, the exploration of high-efficient and earth-abundant materials is of great importance for the future of hydrogen economy, [6][7][8] and it is highly desirable to create a low-cost, robust, and high-active electrocatalyst for HER.In the last decade, abundant transition metal-based electrocatalysts have been reported as the promising alternatives to noble metals for HER, including transition metal chalcogenide, carbides, and nitrides, such as MoS 2 , [9] CoSe 2 , [10] W 2 C, [11] and MoN 4 . [12] In particular, transition metal phosphides (TMPs) have attracted considerable attention in HER, [13][14][15] where CoP has been regarded as one of the best candidates for HER. It has been demonstrated that P atoms in the TMPs can draw electrons from metal and serve as a proton-acceptor, [16,17] and the activity of this kind of catalyst severely depends on the microstructures of CoP. [18] Hence, great efforts have been made to fabricate different morphologies of CoP materials, such as nanoparticles, [19] nanowires, [20,21] nanosheets, [22,23] and nanotube. [24] However, some CoP nanorods or nanoparticles are vulnerable to agglomeration due to the large current density and long-term testing, resulting in degenerative stability and low electrocatalytic activity. [25] Accordingly, it is challengeable but more attractive to develop an electrocatalyst with robust stability and high activity.3D nanoarrays (NA) directly grown on the current collectors have been regarded as popular high-capability electrodes in the past few years. The advantages of 3D nanoarray can be mainly summarized as the following points: 1) The 3D nanostructures could accelerate the desorption of H 2 gas bubbles from catalyst surface and then improve the mass transfer. [26] 2) The 3D structures can avoid the aggregation of electrocatalysts caused by the high current and long-term testing. 3) The self-assembled electrodes possess prominent advantages than that required to be immobilized by polymer binder such as Nafion which will block active sites and inhibit diffusion. [27] In order to further enhance electrocatalytic performances and stability, an effective method is to wrap the nanorods array or nanoparticles (NPs) with carbon layers, which can protect the catalysts from the degradation and agglomeration at performance testing. [28] For Hydrogen evolution reaction (HER) is a key reaction in water splitting, and developing efficient and robust non-noble electrocatalysts for HER is still a great challenge for large-scale hydrogen production. Herein, a vertically aligned core-shell structure grown on Ti foil with CoP nanoarray as a core and N,P-doped carbon (NPC) as a shell (CoP/NPC/TF) is first reported as an efficient electrocatalyst for HER. Results indicate that CoP/NPC/TF only demands the overpotentials of 91 and 80 mV to drive the current density of 10 mA cm −2 in acidic and alkaline solutions. The electrochemical measurements and theoretical calcula...

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Section: Resultsmentioning

confidence: 99%

Vertical CoP Nanoarray Wrapped by N,P‐Doped Carbon for Hydrogen Evolution Reaction in Both Acidic and Alkaline Conditions

Huang

et al. 2019

Advanced Energy Materials

304

139

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“…Then the cuboids with 3D superamolecular framework are assembled by coordination units via hydrogen bonds. [ 33–36 ] According to elemental analysis (Table S1, Supporting Information), the molecular formula of the MOPF cuboids should be denoted as [Cu(PTA) 3 (PTAH)](NO 3 ) 2 ·2H 2 O.…”

Section: Figurementioning

confidence: 99%

“…[ 40 ] The peak at 130.7 eV should be assigned to CuP bond. [ 33 ] Therefore, Cu atoms should be stabilized by CuP bond and CuOP bond, respectively. The P2p spectrum (Figure S10b, Supporting Information) of CUB‐600‐HCl shows that the peak for PO/CuOP at 133.5 eV is obviously decreased.…”

Section: Figurementioning

confidence: 99%

Carbon‐Microcuboid‐Supported Phosphorus‐Coordinated Single Atomic Copper with Ultrahigh Content and Its Abnormal Modification to Na Storage Behaviors

Kong

et al. 2020

Advanced Energy Materials

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as N, B, O, S, and P, has been regarded as one of the most effective methods to boost the Na-ion storage in carbons by creating additional active sites and modifying the electronic structure of carbon. [6] Compared with nonmetal doping, doping of single atomic metal (SAM) is expected to exhibit more promising properties. Theoretical studies have shown that SAM dopants in graphene, such as Be-doped graphene, [7] Be,N dual-doped graphene, [8] and Si,Gecodoped graphene, [9] can enhance diffusion kinetics and provide anchoring sites for alkali metal-ions. SAM doping results in more delocalized electrons than nonmetal doping, enhancing electron conductivity. Additionally, SAMs render stronger affinity and lower migration resistance of alkali metal-ions in carbons. [10] Recent reports show that carbon-supported SAMs not only are being intensively investigated in electrocatalysts, [11] but also arouse great interests in Li-metal batteries [12] and Na-S batteries. [13] However, there is still no experimental investigation about the influence of SAMs on the Na-ion storage as well as other alkali metal-ion storage.Novel methods, such as atomic layer loading, chemical vapor deposition, wet chemistry route, and high-energy ball milling strategy, have been developed to prepare SAM-doped carbons, but they suffer from high cost and low yield. [11,14] Compared with these methods, metal-organic frameworks (MOFs)-derived strategy have gained tremendous popularity to construct carbonsupported SAMs. This method generally involves preparation of MOFs and subsequent pyrolysis. During pyrolysis, metal is exceedingly vulnerable to aggregate, [15] so maintaining single atomic state is a major challenge. Many strategies have been adopted to inhibit metal aggregation such as Zn-evaporation, [16][17][18][19][20][21][22] trapping of uncoordinated groups, [23][24][25] etc. Basic ideas for these methods are to increase the distance between metal atoms and/ or strengthen the interaction between metal and anchoring sites to avoid aggregation. Nevertheless, achieving high content doping of SAMs in MOFs-derived carbon is still a great challenge. [26][27][28][29] Low loading-content severely hinders its practical use in current application fields [11][12][13] and also blocks its expansion in other fields such as SIBs. It is urgent to explore novel MOF-derived stategies to realize high-loading SAMs.Achieving high-content loading of SAMs necessitates enhancing metal-ligand interaction. The MOF precursors for Carbon-supported single atomic metals (SAMs) have aroused great interest in energy conversion and storage fields. However, metal content has to date, been far below expectation. Additionally, theoretical calculations show that SAMs are superb anchoring sites for alkali metal-ion storage, but the experimental research remains untouched. Herein, a metal-organophosphine framework derived strategy is proposed to prepare carbon microcuboidssupported single atomic Cu with a high content of 26.3 wt%. Atomic Cu is stabilized mainly by P moieties, exhibit...

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“…Over the last several decades, several classes of materials have emerged as possible conversion anodes for both micro-and macrobatteries, such as transition metal oxides, [10] carbides, [11] and sulfides. [12] In particular, metal phosphides have displayed strong performance in both lithium-ion [13][14][15] and sodium-ion [16][17][18][19] batteries, owing to their high capacity, good electronic conductivity, and naturally abundant constituent elements.Despite their technological promise, synthesis of metal phosphides has traditionally been challenging due to the flammability and toxicity of common phosphoruscontaining precursors. [20] Simultaneous control over nanostructure, crystal structure, and surface morphology remains imprecise, thereby impeding electrode design and incorporation into devices.…”

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confidence: 99%

Virus‐Templated Nickel Phosphide Nanofoams as Additive‐Free, Thin‐Film Li‐Ion Microbattery Anodes

Records

Wei

Belcher

2019

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Transition metal phosphides are a new class of materials generating interest as alternative negative electrodes in lithium‐ion batteries. However, metal phosphide syntheses remain underdeveloped in terms of simultaneous control over phase composition and 3D nanostructure. Herein, M13 bacteriophage is employed as a biological scaffold to develop 3D nickel phosphide nanofoams with control over a range of phase compositions and structural elements. Virus‐templated Ni5P4 nanofoams are then integrated as thin‐film negative electrodes in lithium‐ion microbatteries, demonstrating a discharge capacity of 677 mAh g–1 (677 mAh cm–3) and an 80% capacity retention over more than 100 cycles. This strong electrochemical performance is attributed to the virus‐templated, nanostructured morphology, which remains electronically conductive throughout cycling, thereby sidestepping the need for conductive additives. When accounting for the mass of additional binder materials, virus‐templated Ni5P4 nanofoams demonstrate the highest practical capacity reported thus far for Ni5P4 electrodes. Looking forward, this synthesis method is generalizable and can enable precise control over the 3D nanostructure and phase composition in other metal phosphides, such as cobalt and copper.

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Metal–Organophosphine Framework‐Derived N,P‐Codoped Carbon‐Confined Cu₃P Nanopaticles for Superb Na‐Ion Storage

Cited by 96 publications

References 51 publications

Vertical CoP Nanoarray Wrapped by N,P‐Doped Carbon for Hydrogen Evolution Reaction in Both Acidic and Alkaline Conditions

Vertical CoP Nanoarray Wrapped by N,P‐Doped Carbon for Hydrogen Evolution Reaction in Both Acidic and Alkaline Conditions

Carbon‐Microcuboid‐Supported Phosphorus‐Coordinated Single Atomic Copper with Ultrahigh Content and Its Abnormal Modification to Na Storage Behaviors

Virus‐Templated Nickel Phosphide Nanofoams as Additive‐Free, Thin‐Film Li‐Ion Microbattery Anodes

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Metal–Organophosphine Framework‐Derived N,P‐Codoped Carbon‐Confined Cu3P Nanopaticles for Superb Na‐Ion Storage

Cited by 96 publications

References 51 publications

Vertical CoP Nanoarray Wrapped by N,P‐Doped Carbon for Hydrogen Evolution Reaction in Both Acidic and Alkaline Conditions

Vertical CoP Nanoarray Wrapped by N,P‐Doped Carbon for Hydrogen Evolution Reaction in Both Acidic and Alkaline Conditions

Carbon‐Microcuboid‐Supported Phosphorus‐Coordinated Single Atomic Copper with Ultrahigh Content and Its Abnormal Modification to Na Storage Behaviors

Virus‐Templated Nickel Phosphide Nanofoams as Additive‐Free, Thin‐Film Li‐Ion Microbattery Anodes

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Metal–Organophosphine Framework‐Derived N,P‐Codoped Carbon‐Confined Cu₃P Nanopaticles for Superb Na‐Ion Storage