Colloidal Ni<sub>2</sub>P Nanocrystals Encapsulated in Heteroatom-Doped Graphene Nanosheets: A Synergy of 0D@2D Heterostructure Toward Overall Water Splitting

Suryawanshi, Umesh P.; Ghorpade, Uma V.; Lee, Dong-Min; He, Mingrui; Shin, Seung Wook; Kumar, Priyank V.; Jang, Jun Sung; Jung, Hyo Rim; Suryawanshi, Mahesh P.; Kim, Jihun

doi:10.1021/acs.chemmater.0c03543

Cited by 65 publications

(34 citation statements)

References 61 publications

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“…The elemental mapping results the presence of elements such as Ni, P, C, N and S confirms the presence of Ni 2 P over NSG (Figure 16g). The catalyst shows high efficiency in both HER and OER as well as in the TWS by keeping Ni 2 P@NSG as both anode and cathode shows the overall cell voltage as 1.57 V at 10 mA cm −2 [63] . The strong interaction of 0D Ni 2 P and the 2D NSG changes the electronic configuration via transferring electron from Ni 2 P. Also, the binding energy change on the intermediate formed with the Ni 2 P@NSG and the heteroatom doping further alters the adsorption energy of the intermediated in the process of OER and HER [9,59] .…”

Section: Transition Metal Phosphide Electrocatalyst For Twsmentioning

confidence: 99%

“…Suryawanshi et al . demonstrated the phase controlled Ni 2 P nanocrystals as an active electrocatalyst for total water splitting in alkaline medium [63] . The colloidal solution of 0D Ni 2 P was synthesised via solution‐phase method and following that the bare graphene was oxidised and hydrothermal treated at 160 °C for 12 h which forms 2D N, S‐doped graphene (NSG) (Figure 15).…”

Section: Transition Metal Phosphide Electrocatalyst For Twsmentioning

confidence: 99%

“…The strong interaction of 0D Ni 2 P and the 2D NSG changes the electronic configuration via transferring electron from Ni 2 P. Also, the binding energy change on the intermediate formed with the Ni 2 P@NSG and the heteroatom doping further alters the adsorption energy of the intermediated in the process of OER and HER [9,59] . The detail of the studies with various nickel phosphides describes the efficiency and durability of the catalyst for TWS application [63] . Following NiP, the transition metal phosphide such as CoP was also studied widely for alkaline water electrolysis and was detailed with the synthesis methods.…”

Section: Transition Metal Phosphide Electrocatalyst For Twsmentioning

confidence: 99%

“…During HER and OER mechanistic steps, the presence of metal phosphides showed enhanced charge transfer with high electrical conductivity of phosphides compared to their own oxide counterparts [16,55–61] . Hence, it is highly desired to visualize the importance of Ni and Co based phosphides towards electrocatalytic water splitting with such high improvements towards AWS [1,62–65] . Figure 2 shows the schematic representation of metal phosphides that can be used as both anode and cathode (bi‐functional catalyst) towards water splitting.…”

Section: Introductionmentioning

confidence: 99%

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Recent Progresses in Engineering of Ni and Co based Phosphides for Effective Electrocatalytic Water Splitting

et al. 2021

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Producing pure hydrogen (H2) is presumably an alternative way for replacing the fossil fuels. Since the last few decades finding alternatives for state‐of‐the‐art catalysts such as IrO2 and RuO2 for oxygen evolution reaction (OER) and platinum for hydrogen evolution reaction (HER) has been a major challenge in the field of water electrolysis. To replace such precious metals, many efforts have been made to develop transition metal based bifunctional catalyst for alkaline water electrolysis. Among them, transition metal phosphides (TMPs) show superior activity in both OER and HER with varying pH conditions. Moreover, the different phases of phosphides, P‐rich or P deficient metal composites (Ni/Co−P) offer a great opportunity in total water splitting (TWS) applications. There is no detailed review in the literature outlining the possible combinations, synthesis methods and morphologies of Ni and Co based phosphides. Based on the above shortage about TMPs as a bi‐functional catalyst for water electrolysis, this review summarizes the activity and stability Ni and Co phosphides. Furthermore, the review highlights monometallic phosphides such as NiP and CoP, bi‐metallic phosphides such as NiCoP, and the synergistic effect of doping Fe into NiP/CoP or Fe ‐NiCoP systems while detailing their preparation methods. Overall, this review extends the role of designing Ni and Co phosphides for efficient large scale electrocatalysis of hydrogen production.

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Section: Transition Metal Phosphide Electrocatalyst For Twsmentioning

confidence: 99%

Section: Transition Metal Phosphide Electrocatalyst For Twsmentioning

confidence: 99%

Section: Transition Metal Phosphide Electrocatalyst For Twsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Recent Progresses in Engineering of Ni and Co based Phosphides for Effective Electrocatalytic Water Splitting

et al. 2021

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“…The relatively higher positive charges of Ni δ+ and the stronger ensemble effect of phosphorous with increasing contents of phosphorous in Ni-P compounds have been reported to improve the catalytic activities especially for HER due to the easier desorption of H 2 ( Pan et al, 2015b ; Menezes et al, 2017 ). The Ni-P electrocatalysts for water splitting have been fabricated by various approaches, such as colloidal synthesis, phosphorylation, physical vapor deposition, chemical vapor deposition, plasma spraying method, and electrodeposition ( Wu and Duh, 2003 ; Mahalingam et al, 2007 ; Panneerselvam et al, 2008 ; Wu and Wu, 2013 ; Cai et al, 2015 ; Kornienko et al, 2017 ; Hasannaeimi and Mukherjee, 2019 ; Kim et al, 2019 ; Suryawanshi et al, 2020 ). The electrodeposition technique can be performed to deposit homogeneous Ni-P electrocatalysts in low temperature and atmospheric pressure without high-cost facilities.…”

Section: Introductionmentioning

confidence: 99%

Electrocatalytic Properties of Pulse-Reverse Electrodeposited Nickel Phosphide for Hydrogen Evolution Reaction

Jeong

Kim

et al. 2021

Front. Chem.

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Nickel phosphide (Ni-P) films as a catalytic cathode for the hydrogen evolution reaction (HER) of a water splitting were fabricated by a pulse-reverse electrodeposition technique. The electrochemical behaviors for the electrodeposition of Ni-P were investigated by the characterization of peaks in a cyclic voltammogram. The composition of the electrodeposited Ni-P alloys was controlled by adjusting duty cycles of the pulse-reverse electrodeposition. The HER electrocatalytic properties of the Ni-P electrodeposits with an amorphous phase as a function of phosphorous contents existing in Ni-P were electrochemically characterized by the analysis of overpotentials, Tafel slopes, and electrochemical impedance spectrometry. Additionally, the elemental Ni-embedded crystalline Ni3P was prepared by an annealing process with the amorphous Ni69P31 electrodeposit with high contents of phosphorus. The crystalline structure with Ni inclusions in the matrix of Ni3P was formed by the precipitation of excess Ni. The electrocatalytic properties of crystalline Ni3P with elemental Ni inclusions were also investigated by electrochemical characterization.

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Elaboration of Ni₂P@C Composites with Hollow Porous Structure for Enhanced Overall Water Splitting

Wang

Ding

Zhao

et al. 2022

Adv Materials Inter

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Ir-based noble metal materials respectively, due to their high activity. But the high cost, resource scarcity, and poor stability of these noble metal materials significantly hamper widespread applications. [4] Accordingly, the development of non-noble metal bifunctional electrocatalysts with superior activity and durability is needed eagerly for HER and OER. [5] Transition metal phosphides (TMPs), benefiting from unique crystal structures, tailorable electronic states, high reactivity and low cost, present a great promise for electrocatalytic water splitting. [6,7] Because the electronegativity of P is higher compared with the metals, the electron density transfer from metal ions to P species, resulting in the superficial metal and P sites act as appropriate hydrideacceptor and proton acceptor centers, respectively. [8] Besides, the introduction of P elements not only weaken the bond strength between the metals (as hydride acceptor) and hydride, but also optimize the behavior of the absorption and desorption of intermediates to facilitate the charge transport process and accelerate the generation of hydrogen and oxygen. [9,10] Since 2005, nickel phosphide (Ni 2 P) has been indicated the potential superiority as HER catalysts by Liu and Rodriguez, due to the structural and electronic similarities to biological hydrogen-evolving catalyst [NiFe] hydrogenases enzyme, based on density functional theory (DFT) calculations. [11] In 2013, Popczun and co-workers reported that hollow Ni 2 P nanoparticles with a high density of the exposed (001) crystal plane have been experimentally confirmed the high HER electrocatalytic. [9] Moreover, Ni 2 P is reported to serve as an interesting pre-catalyst toward the OER. For example, Song et al. developed a Janus structure Ni 2 P catalyst, the core-shell Ni 2 P/NiO x act as the active form for OER, generating in situ under catalytic conditions, and the alkaline electrolyzer achieve the overall water splitting with a current density of 10 mA cm -2 at 1.63 V. [12] Sun et al. synthesized porous multishelled Ni 2 P hollow microspheres with large surface area and abundant interior space facilitate to the ion diffusion and reaction kinetic. [13] Additionally, an extra NiOOH layer is formed under anodic polarization, and the Ni 2 P/NiOOH derivative is superior to RuO 2 catalysts for catalyzing OER. Even so, their intrinsic activity for overall water splitting is kinetically retarded owing to the poor stability and insufficient conductivity.The electrocatalytic water splitting is greatly affected by overpotential, stability, and accessibility of active sites. Designing appropriate active components and tailoring their microstructure are crucial to improve electrocatalytic performance. Herein, using metal organic framework (MOF) as template, novel Ni 2 P@C composites are prepared as bifunctional catalysts for hydrogen evolution reaction (HER) and oxygen evolution reaction (OER). The best Ni 2 P@C-350 sample has a small onset overpotential (η) of 57 mV, and up to 148 and 285 mV to afford 10 a...

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Colloidal Ni₂P Nanocrystals Encapsulated in Heteroatom-Doped Graphene Nanosheets: A Synergy of 0D@2D Heterostructure Toward Overall Water Splitting

Cited by 65 publications

References 61 publications

Recent Progresses in Engineering of Ni and Co based Phosphides for Effective Electrocatalytic Water Splitting

Recent Progresses in Engineering of Ni and Co based Phosphides for Effective Electrocatalytic Water Splitting

Electrocatalytic Properties of Pulse-Reverse Electrodeposited Nickel Phosphide for Hydrogen Evolution Reaction

Elaboration of Ni₂P@C Composites with Hollow Porous Structure for Enhanced Overall Water Splitting

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Colloidal Ni2P Nanocrystals Encapsulated in Heteroatom-Doped Graphene Nanosheets: A Synergy of 0D@2D Heterostructure Toward Overall Water Splitting

Cited by 65 publications

References 61 publications

Recent Progresses in Engineering of Ni and Co based Phosphides for Effective Electrocatalytic Water Splitting

Recent Progresses in Engineering of Ni and Co based Phosphides for Effective Electrocatalytic Water Splitting

Electrocatalytic Properties of Pulse-Reverse Electrodeposited Nickel Phosphide for Hydrogen Evolution Reaction

Elaboration of Ni2P@C Composites with Hollow Porous Structure for Enhanced Overall Water Splitting

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Product

Resources

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Colloidal Ni₂P Nanocrystals Encapsulated in Heteroatom-Doped Graphene Nanosheets: A Synergy of 0D@2D Heterostructure Toward Overall Water Splitting

Elaboration of Ni₂P@C Composites with Hollow Porous Structure for Enhanced Overall Water Splitting