Boosting the catalytic activity of Pd-nanocatalysts by anchoring transition metal atoms on carbon supports for formic acid dehydrogenation

Wang, Qiuju; Zhou, Tianyou; Wang, Chunhui; Li, Longwei; Zou, Lianli

doi:10.1016/j.apsusc.2024.159875

Applied Surface Science

2024

DOI: 10.1016/j.apsusc.2024.159875

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Boosting the catalytic activity of Pd-nanocatalysts by anchoring transition metal atoms on carbon supports for formic acid dehydrogenation

Qiuju Wang,

Tianyou Zhou,

Chunhui Wang

et al.

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Cited by 3 publications

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“…In addition, other hydrogen storage methods, such as large specific surface area materials for adsorption hydrogen storage, [9][10][11] hydrogen storage alloys, [12][13][14][15] chemical hydrides, [16][17][18][19] and other materials 20 have also been constantly receiving attention and research. Among them, chemical hydrides, such as metal borohydrides (NaBH 4 ), [21][22][23][24][25][26][27] ammonia borane (AB) (NH 3 BH 3 ), [28][29][30][31][32] hydrous hydrazine (HH) (N 2 H 4 • H 2 O), [33][34][35][36] hydrazine borane (HB, N 2 H 4 BH 3 ), [37][38][39] and formic acid (FA, HCOOH) [40][41][42][43] have high hydrogen content and stable physical and chemical properties at room temperature, making them easy to store and transport safely and have great application prospects. In addition, the above chemical hydrides can achieve liquid-phase catalytic hydrogen production under mild conditions, and the hydrogen production reaction starts quickly and is easy to control.…”

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Hydrogen production from chemical hydrogen storage materials over copper‐based catalysts

Long,

Wu,

Liu

et al. 2024

cMat

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Hydrogen, as a clean and efficient energy source, is one of the important energy carriers in the future. However, the safe storage and delivery of hydrogen is still a bottleneck in its practical applications. Chemical hydrides (such as NaBH4, NH3BH3, N2H4·H2O, N2H4BH3, and HCOOH) are considered as potential chemical hydrogen storage materials that can achieve rapid on‐site hydrogen production. At present, the most critical issue for them is to develop economic catalysts to achieve efficient hydrogen production from chemical hydrides. Copper (Cu) is considered as a promising catalyst that is one of the most reactive metals among the first‐row transition metals and economically cheap. In this review, we outline the recent advancements of Cu‐based catalysts in catalyzing hydrogen production from chemical hydrides. Moreover, the synthesis methods, characterization techniques, and hydrogen production catalytic activity of Cu‐based catalysts were also introduced. Finally, a brief conclusion and outlook are given for the application of Cu‐based catalysts in the dehydrogenation of chemical hydrides. We hope that this review will stimulate interest in the promising research area of Cu‐based catalysts for the dehydrogenation of chemical hydrides.

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confidence: 99%

Hydrogen production from chemical hydrogen storage materials over copper‐based catalysts

Long,

Wu,

Liu

et al. 2024

cMat

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Synergistic Electronic Interaction in PdCu Alloy/TiO₂‐NSs for Ambient Efficient Dehydrogenation of Formic Acid

Ashraf,

Liu,

Liu

et al. 2024

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Palladium‐based catalysts are remarkable in endorsing hydrogen (H2) generation through formic acid (HCOOH, FA) dehydrogenation under near‐ambient conditions. Hydrogen energy efficiency depends on high‐performance catalyst design. In this study, Pd‐Cu nanoalloy catalysts with mutable atomic ratios are successfully fabricated on TiO2 nanosheets (TiO2‐NSs).The synergistic electronic interactions between Palladium (Pd) and copper (Cu) are revealed through a density of states (DOS) analysis of alloy supported over a mixed valence state of Ti linked to oxygen vacancies (Vo) in TiO2‐NSs, Enhanced adsorption of target molecules reveals novel active sites for Formic acid dehydrogenation (FAD), with O─H bond cleavage via HCOO formate intermediate preceding C─H and C─O bond cleavage. Experimental and theoretical research demonstrates that the Pd‐Cu/TiO2‐NSs (3:7) catalyst d electron redistribution and d‐band center shift lower the activation energy for O─H bond cleavage, exhibit superior H2 production than pure Pd and Cu, increasing Pd electron density due to synergistic effects from reactive crystal facets, defects, and strong metal support interactions (SMSI), lowering the activation energy for HCOOH dissociation step, generating carbon dioxide (CO2) and H2 with a unprecedented high turnover frequency (TOF) of 6268 molH2.h−1.molPd−1 at 303K with activation energy (Ea) of 15 KJ mol−1. This attempt models an efficient HCOOH‐to‐hydrogen catalyst.

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Atomically precise MOF-Based electrocatalysts by design: Hydrogen evolution applications

Areeb Amjad,

Murtaza,

Shoaib Ahmad Shah

et al. 2025

Fuel

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Boosting the catalytic activity of Pd-nanocatalysts by anchoring transition metal atoms on carbon supports for formic acid dehydrogenation

Cited by 3 publications

References 38 publications

Hydrogen production from chemical hydrogen storage materials over copper‐based catalysts

Hydrogen production from chemical hydrogen storage materials over copper‐based catalysts

Synergistic Electronic Interaction in PdCu Alloy/TiO₂‐NSs for Ambient Efficient Dehydrogenation of Formic Acid

Atomically precise MOF-Based electrocatalysts by design: Hydrogen evolution applications

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Boosting the catalytic activity of Pd-nanocatalysts by anchoring transition metal atoms on carbon supports for formic acid dehydrogenation

Cited by 3 publications

References 38 publications

Hydrogen production from chemical hydrogen storage materials over copper‐based catalysts

Hydrogen production from chemical hydrogen storage materials over copper‐based catalysts

Synergistic Electronic Interaction in PdCu Alloy/TiO2‐NSs for Ambient Efficient Dehydrogenation of Formic Acid

Atomically precise MOF-Based electrocatalysts by design: Hydrogen evolution applications

Contact Info

Product

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Synergistic Electronic Interaction in PdCu Alloy/TiO₂‐NSs for Ambient Efficient Dehydrogenation of Formic Acid