Iron Phosphide Incorporated into Iron‐Treated Heteroatoms‐Doped Porous Bio‐Carbon as Efficient Electrocatalyst for the Oxygen Reduction Reaction

Tran, Tri; Song, Min Young; Kang, Tong‐Hyun; Samdani, Jitendra; Park, Hyean-Yeol; Kim, Hasuck; Jhung, Sung Hwa; Yu, Jong‐Sung

doi:10.1002/celc.201800091

Cited by 30 publications

(21 citation statements)

References 82 publications

(89 reference statements)

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“…Despite numerous attempts to exploit low‐cost and efficient non‐precious metal electrocatalysts to substitute traditional platinum‐based catalysts for oxygen reduction reaction (ORR) in the last several decades, it is still a long way for the large‐scale commercialization of these electrocatalysts in clean energy devices such as fuel cells and metal‐air batteries . In order to fulfil the requirements of the large‐scale commercial application, it is very crucial to seek the novel low‐cost non‐noble metal electrocatalysts with the higher ORR catalytic activity and durability.…”

Section: Introductionmentioning

confidence: 53%

“…[1][2][3][4][5] In order to fulfil the requirements of the large-scale commercial application,i ti sv ery crucial to seek the novel low-cost nonnoble metal electrocatalysts with the higher ORR catalytic activity and durability.C opper,w ith abundantr eserves and low costs, only one electron away from platinum in amount of the de lectrons in the secondary outer shell of the atom, has attracted much attention. [1][2][3][4][5] In order to fulfil the requirements of the large-scale commercial application,i ti sv ery crucial to seek the novel low-cost nonnoble metal electrocatalysts with the higher ORR catalytic activity and durability.C opper,w ith abundantr eserves and low costs, only one electron away from platinum in amount of the de lectrons in the secondary outer shell of the atom, has attracted much attention.…”

Section: Introductionmentioning

confidence: 99%

“…Despite numerous attempts to exploit low-cost and efficient non-precious metal electrocatalysts to substitute traditional platinum-based catalysts for oxygen reduction reaction (ORR) in the last severald ecades, it is stillal ong way for the largescale commercialization of these electrocatalysts in clean energy devicess uch as fuel cells and metal-air batteries. [1][2][3][4][5] In order to fulfil the requirements of the large-scale commercial application,i ti sv ery crucial to seek the novel low-cost nonnoble metal electrocatalysts with the higher ORR catalytic activity and durability.C opper,w ith abundantr eserves and low costs, only one electron away from platinum in amount of the de lectrons in the secondary outer shell of the atom, has attracted much attention. The half-wavep otential for ORR over the Cu particles encapsulated in N-doped carbon shells reached0 .83 V RHE (relative to the reversible hydrogen electrode) and was 20 mV lower than that over the commercial Pt/ Cc atalyst.…”

Section: Introductionmentioning

confidence: 99%

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Pyrolytic Carbon‐coated Cu‐Fe Alloy Nanoparticles with High Catalytic Performance for Oxygen Electroreduction

Qiao

Kong

et al. 2019

Chemistry An Asian Journal

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Well-dispersed carbon-coated or nitrogen-doped carbon-coated copper-iron alloy nanoparticles (FeCu@Co r FeCu@CÀN) in carbon-based supports are obtained using a bimetallic metal-organic framework (Cu/Fe-MOF-74)o ra mixture of Cu/Fe-MOF-74 and melamine as sacrificial templates and an active-component precursor by using apyrolysis method.T he investigation resultsa ttest formation of CuÀ Fe alloy nanoparticles. The obtained FeCu@Cc atalyst exhibits ac atalytic activity with ah alf-wave potential of 0.83 Vf or oxygen reduction reaction (ORR) in alkalinem edium, comparable to that on commercial Pt/C catalyst (0.84 V).T he cata-lytic activity of FeCu@CÀNf or ORR (E half-wave = 0.87 V) outshinesa ll reported analogues. The excellent performance of FeCu@CÀNs hould be attributedt oachange in the energy of the d-band center of Cu resulting from the formationo f the copper-iron alloy,t he interaction between alloy nanoparticlesa nd supports and N-dopingi nt he carbon matrix. Moreover,F eCu@C and FeCu@CÀNs how better electrochemicals tability and methanol tolerance than commercial Pt/C and are expected to be widely used in practical applications.

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Section: Introductionmentioning

confidence: 53%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Pyrolytic Carbon‐coated Cu‐Fe Alloy Nanoparticles with High Catalytic Performance for Oxygen Electroreduction

Qiao

Kong

et al. 2019

Chemistry An Asian Journal

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“…Heteroatom doping (e.g., N) in a carbon structure could induce charge redistribution to make adjacent carbon atoms as the active sites for the ORR. [ 188 ] In the phosphide@carbon hybrid‐type catalysts, although the encased phosphides didn't contact with the oxygen intermediates directly during the ORR process, they still could activate the surrounding graphitic carbon layer synergistically, endowing the carbon layer with high activity toward the ORR. For instance, Lin and co‐workers reported a CoP/defective carbon (DC) hybrid (Figure 7d,e), where the interfacial polarized electrons accumulated at the surface of DC contributed to the enhanced ORR activity, and the holes accumulated at CoP nanoparticles were helpful to the OER process, as demonstrated by their electrochemical tests (Figure 7f–h).…”

Section: Phosphidesmentioning

confidence: 99%

Phosphorus‐Based Electrocatalysts: Black Phosphorus, Metal Phosphides, and Phosphates

Wang

2020

Adv Materials Inter

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their efficiencies, the catalysts employed are basically required to overcome the high energy barriers and sluggish kinetics of the electrochemical HER, OER, and ORR. [3] The benchmarking catalysts for ORR and HER are platinum (Pt)-based noble metal catalysts, whereas iridium (Ir) and ruthenium (Ru) oxides are highly active toward the OER. [4] Nevertheless, the high cost and scarcity of these precious metal-based catalysts have notably hindered their wide applications and commercialization. [5] Therefore, developing highly active, low cost, and sustained catalysts for these key electrocatalytic processes is paramount and apparently rewarding for the sustainable and large-scale implementation of clean energy devices. [6] To reduce, and hopefully to eliminate the usage of these precious metal-based catalysts, there have been intensive researches, in order to develop the practically and economically viable alternative electrocatalysts. [7] In this connection, phosphorus (P) is one of the most earth-abundant elements, thereby P-based materials have been considered being employed for electrocatalysis. [8] Indeed, P-based inorganic materials, especially the black phosphorus, metal phosphides, and metal phosphates, have attracted immense attention recently as a class of promising electrocatalysts, and presented intrinsic electrochemical activity and widely tunable properties. [9] Black phosphorus (BP) is a layer-structured semiconductor, in which individual atomic layers are stacked and held together by van der Waals interactions. [10,11] Until recently, BP stands out as a group of promising catalysts that have been investigated and shown to exhibit catalytic activities, owing to their unique puckered layer-structure, tunable band gap, and high carrier mobility. [12,13] As suggested by recent researches, 2D catalysts with reduced layer numbers or the thickness can present increased surface area and hence expose additional active sites, in comparison with their bulk counterparts. [14] To this end, phosphorene, as the building block for BP, possesses a monolayer (or a few layer) sheet structure, and has been explored for electrocatalysis and expected to promote the catalytic efficiency. [15,16] Nevertheless, because of the densely packed lone-pair p-electrons of phosphorus atoms, it would be hard for phosphorene to adsorb hydrogen, leading to the large hydrogen adsorption energy, and thus poor HER electrocatalytic Enormous progresses have been made in developing advanced energy conversion and storage technologies, which inevitably require high-performance electrocatalysts. Recently, phosphorus (P)-based materials have drawn tremendous attention as a class of promising electrocatalysts and presented intrinsic electrochemical activity and widely tunable property. In a timely response to the ongoing interests, issues faced in P-based inorganic materials, and the approaches to address them in relation to energy conversion reactions, including hydrogen evolution reaction, oxygen evolution reaction, and oxygen reduction reactio...

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“…Nevertheless, the chemical properties of HTCs need to be modified in order to approach the outstanding electrochemical performance of Pt-electrocatalyst reference materials [23,24]. These modifications can be achieved by the incorporation of heteroatoms like nitrogen, sulfur, phosphorus, or boron and/or advanced carbon materials like graphene oxide or carbon nanotubes (CNTs) [9,12,13,17,[25][26][27][28]. Nitrogen is the most promising heteroatom for ORR, as pyridinic nitrogen favors the bonding of oxygen to the adjacent carbon, while the presence of quaternary nitrogen favors oxygen dissociation [7,29].…”

Section: Introductionmentioning

confidence: 99%

Hydrothermal Carbon/Carbon Nanotube Composites as Electrocatalysts for the Oxygen Reduction Reaction

et al. 2020

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The oxygen reduction reaction is an essential reaction in several energy conversion devices such as fuel cells and batteries. So far, the best performance is obtained by using platinum-based electrocatalysts, which make the devices really expensive, and thus, new and more affordable materials should be designed. Biomass-derived carbons were prepared by hydrothermal carbonization in the presence of carbon nanotubes with different oxygen surface functionalities to evaluate their effect on the final properties. Additionally, nitrogen functional groups were also introduced by ball milling the carbon composite together with melamine. The oxygen groups on the surface of the carbon nanotubes favor their dispersion into the precursor mixture and the formation of a more homogenous carbon structure with higher mechanical strength. This type of structure partially avoids the crushing of the nanotubes and the carbon spheres during the ball milling, resulting in a carbon composite with enhanced electrical conductivity. Undoped and N-doped composites were used as electrocatalysts for the oxygen reduction reaction. The onset potential increases by 20% due to the incorporation of carbon nanotubes (CNTs) and nitrogen, which increases the number of active sites and improves the chemical reactivity, while the limiting current density increases by 47% due to the higher electrical conductivity.

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Iron Phosphide Incorporated into Iron‐Treated Heteroatoms‐Doped Porous Bio‐Carbon as Efficient Electrocatalyst for the Oxygen Reduction Reaction

Cited by 30 publications

References 82 publications

Pyrolytic Carbon‐coated Cu‐Fe Alloy Nanoparticles with High Catalytic Performance for Oxygen Electroreduction

Pyrolytic Carbon‐coated Cu‐Fe Alloy Nanoparticles with High Catalytic Performance for Oxygen Electroreduction

Phosphorus‐Based Electrocatalysts: Black Phosphorus, Metal Phosphides, and Phosphates

Hydrothermal Carbon/Carbon Nanotube Composites as Electrocatalysts for the Oxygen Reduction Reaction

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