Your search keyword '"Hydrogen spillover"' showing total 128 results

1. Electronic Metal‐Support Interaction Induces Hydrogen Spillover and Platinum Utilization in Hydrogen Evolution Reaction.

Author

Feng, Yumei, Xie, Yuhua, Yu, Yingjie, Chen, Yazhou, Liu, Qingting, Bao, Haifeng, Luo, Fang, Pan, Shuyuan, and Yang, Zehui

Subjects

HYDROGEN evolution reactions, GIBBS' free energy, HYDROGEN as fuel, ACTIVATION energy, CARBON-black, PLATINUM

Abstract

The substantial promotion of hydrogen evolution reaction (HER) catalytic performance relies on the breakup of the Sabatier principle, which can be achieved by the alternation of the support and electronic metal support interaction (EMSI) is noticed. Due to the utilization of tungsten disulfides as support for platinum (Pt@WS2), surprisingly, Pt@WS2 demands only 31 mV overpotential to attain 10 mA cm−2 in acidic HER test, corresponding to a 2.5‐fold higher mass activity than benchmarked Pt/C. The pH dependent electrochemical measurements associated with H2‐TPD and in situ Raman spectroscopy indicate a hydrogen spillover involved HER mechanism is confirmed. The WS2 support triggers a higher hydrogen binding strength for Pt leading to the increment in hydrogen concentration at Pt sites proved by upshifted d band center as well as lower Gibbs free energy of hydrogen, favourable for hydrogen spillover. Besides, the WS2 shows a comparably lower effect on Gibbs free energy for different Pt layers (−0.50 eV layer−1) than carbon black (−0.88 eV layer−1) contributing to a better Pt utilization. Also, the theoretical calculation suggests the hydrogen spillover occurs on the 3rd Pt layer in Pt@WS2; moreover, the energy barrier is lowered with increment in hydrogen coverage on Pt. Therefore, the boosted HER activity attributes to the EMSI effect caused hydrogen spillover and enhancement in Pt utilization efficiency. [ABSTRACT FROM AUTHOR]

Published

2025

2. Electronic Metal‐Support Interaction Induces Hydrogen Spillover and Platinum Utilization in Hydrogen Evolution Reaction.

Author

Feng, Yumei, Xie, Yuhua, Yu, Yingjie, Chen, Yazhou, Liu, Qingting, Bao, Haifeng, Luo, Fang, Pan, Shuyuan, and Yang, Zehui

Subjects

HYDROGEN evolution reactions, GIBBS' free energy, HYDROGEN as fuel, ACTIVATION energy, CARBON-black, PLATINUM

Abstract

The substantial promotion of hydrogen evolution reaction (HER) catalytic performance relies on the breakup of the Sabatier principle, which can be achieved by the alternation of the support and electronic metal support interaction (EMSI) is noticed. Due to the utilization of tungsten disulfides as support for platinum (Pt@WS2), surprisingly, Pt@WS2 demands only 31 mV overpotential to attain 10 mA cm−2 in acidic HER test, corresponding to a 2.5‐fold higher mass activity than benchmarked Pt/C. The pH dependent electrochemical measurements associated with H2‐TPD and in situ Raman spectroscopy indicate a hydrogen spillover involved HER mechanism is confirmed. The WS2 support triggers a higher hydrogen binding strength for Pt leading to the increment in hydrogen concentration at Pt sites proved by upshifted d band center as well as lower Gibbs free energy of hydrogen, favourable for hydrogen spillover. Besides, the WS2 shows a comparably lower effect on Gibbs free energy for different Pt layers (−0.50 eV layer−1) than carbon black (−0.88 eV layer−1) contributing to a better Pt utilization. Also, the theoretical calculation suggests the hydrogen spillover occurs on the 3rd Pt layer in Pt@WS2; moreover, the energy barrier is lowered with increment in hydrogen coverage on Pt. Therefore, the boosted HER activity attributes to the EMSI effect caused hydrogen spillover and enhancement in Pt utilization efficiency. [ABSTRACT FROM AUTHOR]

Published

2025

3. Mechanism of the Cojoint Effect of Components of the Ni/HMOR/–ZrO2 Catalytic System on the Hydroconversion of Aromatic Hydrocarbons.

Author

Abasov, S. I., Isaeva, E. S., Agaeva, S. B., Mamedova, M. T., Iskenderova, A. A., and Imanova, A. A.

Abstract

Composite catalyst (CC) Ni/HMOR/ –ZrO2 is used to study the hydroconversion of benzene and toluene at atmospheric pressure, a temperature of 180°C, WHSV = 2 h−1, and Н2/ArH = 8. The conversion of benzene is as high as 58.2%. Adding an alkyl substituent raises conversion to 78.5%. It is shown that the primary conversion of toluene is similar to the conversion of benzene through selective aromatic ring hydrogenation with its subsequent isomerization, ring reduction, and hydrocleavage. Components of the catalytic system are inactive in the hydroconversion of aromatic hydrocarbons. Synergism emerges in the hydrogenating CC activity due to the cojoint effect which individual inactive –ZrO2 and Ni/HMOR components of this system have on the reaction. The probable mechanism of the hydrogenation of aromatic hydrocarbons is discussed. It is hypothesized that hydrogenating activity synergism results from the radical reaction becoming one of an ion radical. [ABSTRACT FROM AUTHOR]

Published

2024

4. Maximizing Bifunctionality for Overall Water Splitting by Integrating H2 Spillover and Oxygen Vacancies in CoPBO/Co3O4 Composite Catalyst.

Author

Bhabal, Rinkoo, Bhide, Aniruddha, Gupta, Suraj, Fernandes, Rohan, and Patel, Nainesh

Subjects

WATER electrolysis, GREEN fuels, HYDROGEN evolution reactions, RENEWABLE energy sources, GIBBS' free energy

Abstract

In the pursuit of utilizing renewable energy sources for green hydrogen (H2) production, alkaline water electrolysis has emerged as a key technology. To improve the reaction rates of overall water electrolysis and simplify electrode manufacturing, development of bifunctional electrocatalysts is of great relevance. Herein, CoPBO/Co3O4 is reported as a binary composite catalyst comprising amorphous (CoPBO) and crystalline (Co3O4) phases as a high‐performing bifunctional electrocatalyst for alkaline water electrolysis. Owing to the peculiar properties of CoPBO and Co3O4, such as complementing Gibbs free energy values for H‐adsorption (ΔGH) and relatively smaller difference in their work functions (ΔΦ), the composite exhibits H2 spillover (HS) mechanism to facilitate the hydrogen evolution reaction (HER). The outcome is manifested in the form of a low HER overpotential of 65 mV (at 10 mA cm−2). Moreover, an abundant amount of surface oxygen vacancies (Ov) are observed in the same CoPBO/Co3O4 composite that facilitates oxygen evolution reaction (OER) as well, leading to a mere 270 mV OER overpotential (at 10 mA cm−2). The present work showcases the possibilities to strategically design non‐noble composite catalysts that combine the advantages of HS phenomenon as well as Ov to achieve new record performances in alkaline water electrolysis. [ABSTRACT FROM AUTHOR]

Published

2024

5. S−S Bond Strategy at Sulfide Heterointerface: Reversing Charge Transfer and Constructing Hydrogen Spillover for Boosted Hydrogen Evolution.

Author

Yue, Haoyu, Guo, Zhongnan, Zhou, Ziwen, Zhang, Xuemeng, Guo, Wenjing, Zhen, Shuang, Wang, Pu, Wang, Kang, and Yuan, Wenxia

Subjects

CHARGE transfer, HYDROGEN sulfide, OXYGEN evolution reactions, THERMODYNAMICS, SULFIDES, HYDROGEN evolution reactions, OVERPOTENTIAL, ELECTROCATALYSTS

Abstract

Developing efficient electrocatalyst in sulfides for hydrogen evolution reaction (HER) still poses challenges due to the lack of understanding the role of sulfide heterointerface. Here, we report a sulfide heterostructure RuSx/NbS2, which is composed of 3R‐type NbS2 loaded by amorphous RuSx nanoparticles with S−S bonds formed at the interface. As HER electrocatalyst, the RuSx/NbS2 shows remarkable low overpotential of 38 mV to drive a current density of 10 mA cm−2 in acid, and also low Tafel slope of 51.05 mV dec−1. The intrinsic activity of RuSx/NbS2 is much higher than that of Ru/NbS2 reference as well as the commercial Pt/C. Both experiments and theoretical calculations unveil a reversed charge transfer at the interface from NbS2 to RuSx that driven by the formation of S−S bonds, resulting in electron‐rich Ru configuration for strong hydrogen adsorption. Meanwhile, electronic redistribution induced by the sulfide heterostructure facilitates hydrogen spillover (HSo) effect in this system, leading to accelerated hydrogen desorption at the basal plane of NbS2. This study provides an effective S−S bond strategy in sulfide heterostructure to synergistically modulate the charge transfer and adsorption thermodynamics, which is very valuable for the development of efficient electrocatalysts in practical applications. [ABSTRACT FROM AUTHOR]

Published

2024

6. S−S Bond Strategy at Sulfide Heterointerface: Reversing Charge Transfer and Constructing Hydrogen Spillover for Boosted Hydrogen Evolution.

Author

Yue, Haoyu, Guo, Zhongnan, Zhou, Ziwen, Zhang, Xuemeng, Guo, Wenjing, Zhen, Shuang, Wang, Pu, Wang, Kang, and Yuan, Wenxia

Subjects

CHARGE transfer, HYDROGEN sulfide, OXYGEN evolution reactions, THERMODYNAMICS, SULFIDES, HYDROGEN evolution reactions, OVERPOTENTIAL, ELECTROCATALYSTS

Abstract

Developing efficient electrocatalyst in sulfides for hydrogen evolution reaction (HER) still poses challenges due to the lack of understanding the role of sulfide heterointerface. Here, we report a sulfide heterostructure RuSx/NbS2, which is composed of 3R‐type NbS2 loaded by amorphous RuSx nanoparticles with S−S bonds formed at the interface. As HER electrocatalyst, the RuSx/NbS2 shows remarkable low overpotential of 38 mV to drive a current density of 10 mA cm−2 in acid, and also low Tafel slope of 51.05 mV dec−1. The intrinsic activity of RuSx/NbS2 is much higher than that of Ru/NbS2 reference as well as the commercial Pt/C. Both experiments and theoretical calculations unveil a reversed charge transfer at the interface from NbS2 to RuSx that driven by the formation of S−S bonds, resulting in electron‐rich Ru configuration for strong hydrogen adsorption. Meanwhile, electronic redistribution induced by the sulfide heterostructure facilitates hydrogen spillover (HSo) effect in this system, leading to accelerated hydrogen desorption at the basal plane of NbS2. This study provides an effective S−S bond strategy in sulfide heterostructure to synergistically modulate the charge transfer and adsorption thermodynamics, which is very valuable for the development of efficient electrocatalysts in practical applications. [ABSTRACT FROM AUTHOR]

Published

2024

7. Application of Hydrogen Spillover to Enhance Alkaline Hydrogen Evolution Reaction.

Author

Pan, Shuyuan, Luo, Fang, and Yang, Zehui

Subjects

HYDROGEN evolution reactions, HYDROGEN production, ELECTROCATALYSTS, OVERPOTENTIAL, HYDROGEN

Abstract

Alkaline water splitting has shown great potential for industrial‐scale hydrogen production. However, its broad application is constrained by hydrogen evolution reaction (HER) electrocatalysts, which struggle to achieve optimal current density at low overpotential. The utilization of the hydrogen spillover effect to augment the performance of HER represents a burgeoning area of research. Although previous studies mainly focused on hydrogen spillover in acidic media, the latest studies have shown that hydrogen spillover also exists under alkaline conditions, and its role in improving HER performance cannot be ignored. This review examines the mechanisms of HER under acidic and alkaline conditions, elucidating the distinctive behavior of hydrogen spillover in these environments and its influence on catalytic processes. At the same time hydrogen spillover characterization methods are systematically summarized, these technologies for understanding and control of hydrogen release process provides strong support. Finally, the recent electrocatalysts that enhance the catalytic performance of alkaline HER by hydrogen spillover effect are comprehensively sorted out and summarized. This review not only demonstrate the practical value of hydrogen spillover under alkaline conditions, but also provide new directions for future design and optimization of electrocatalysts. [ABSTRACT FROM AUTHOR]

Published

2024

8. Promoting Effect of Pd Nanoparticles on SrTi0.8Mn0.2O3 in the Reverse Water‐Gas Shift Reaction via the Mars–Van Krevelen Mechanism.

Author

Kobayashi, Minori, Naniwa, Shimpei, Goto, Keita, Matsuo, Hiroki, Iguchi, Shoji, Tanaka, Tsunehiro, and Teramura, Kentaro

Subjects

FOURIER transform infrared spectroscopy, METAL catalysts, HIGH temperatures, WATER-gas, CARBON dioxide

Abstract

The reverse water‐gas shift (RWGS) reaction serves as a critical pathway for converting CO2 into diverse chemicals. The Mars–van Krevelen (MvK) mechanism, which leverages lattice oxygen as the oxidant and oxygen vacancies as reductants, offers an alternative catalytic strategy for the selective RWGS reaction. While Mn‐substituted SrTiO3 (i. e., SrTi0.8Mn0.2O3) has been shown to promote the RWGS reaction selectively via the MvK mechanism, achieving a sufficient conversion of CO2 necessitates elevated temperatures. This study investigated the effect of Pd‐loaded SrTi0.8Mn0.2O3 on the activation of adsorbed H2 molecules, which generated oxygen vacancies and enhanced CO2 conversion. Notably, 1.0 wt % Pd‐loaded SrTi0.8Mn0.2O3 yielded 13.4 % of CO at 673 K, whereas pristine SrTi0.8Mn0.2O3 and Pd‐loaded SrTiO3 yielded negligible or minimal amount of CO. Hydrogen temperature‐programmed reduction and X‐ray absorption spectroscopy measurements revealed that Pd promoted the formation of oxygen vacancies via both thermodynamic and kinetic mechanisms. Fourier transform infrared spectroscopy and kinetic studies revealed that the RWGS reaction over Pd‐loaded SrTi0.8Mn0.2O3 proceeded primarily via the MvK mechanism with a partial contribution from the Langmuir–Hinshelwood mechanism. This study underscores the effectiveness of combining metal and MvK‐type catalysts to enhance the efficiency of the RWGS reaction. [ABSTRACT FROM AUTHOR]

Published

2024

9. Modulating the Hydrogenation Mechanism of Electrochemical CO2 Reduction Using Ruthenium Atomic Species on Bismuth.

Author

Liu, Xiao, Zhen, Cheng, Wu, Junxiu, You, Xiao, Wu, Yudong, Hao, Qi, Yu, Gang, Gu, M. Danny, Liu, Kai, and Lu, Jun

Subjects

ACTIVATION energy, ELECTROLYTIC reduction, ATOMIC hydrogen, BISMUTH, RUTHENIUM

Abstract

The conversion of CO2 into formate through electrochemical methods is emerging as an elegant approach for industrial‐scale CO2 utilization in the near future. Although Bismuth (Bi)‐based materials have shown promise thank to their excellent selectivity, their limited reactivity remains a challenge. Herein, this study demonstrates a significant enhancement in the CO2‐to‐formate efficiency of Bi by incorporating ruthenium (Ru) atomic species. Ru single atom doped Bi exhibited a nearly twofold higher partial current density compared with pure Bi and Ru clusters doped Bi, while over 95% Faradaic efficiency (FE) is maintained. Through comprehensive investigations using a combined approach of electrochemical techniques, operando spectroscopy, and theoretical calculations, this study elucidates that the presence of Ru single atom promotes H2O dissociation and H* migration to Bi sites for CO2‐to‐formate conversion by significantly reducing the energy barrier via a H* spillover path. Besides, it is constructed Ru–Bi bridge sites for efficient CO2 hydrogenation via a non‐spillover path, which served as the major mechanism for CO2‐to‐formate conversion in Ru single atom doped Bi. [ABSTRACT FROM AUTHOR]

Published

2024

10. Heterogeneous Structure of Ni–Mo Nanoalloys Decorated on MoOx for an Efficient Hydrogen Evolution Reaction Using Hydrogen Spillover.

Author

Song, DongHoon, Roh, Jeonghan, Choi, Jungwoo, Lee, Hyein, Koh, Gyungmo, Kwon, YongKeun, Kim, HyoWon, Lee, Hyuck Mo, Kim, MinJoong, and Cho, EunAe

Subjects

HYDROGEN evolution reactions, ELECTROCHEMICAL analysis, HETEROGENEOUS catalysts, DENSITY functional theory, HYDROGEN atom, OXYGEN evolution reactions

Abstract

Herein, a heterogeneous structure of Ni–Mo catalyst comprising Ni4Mo nanoalloys decorated on a MoOx matrix via electrodeposition is introduced. This catalyst exhibits remarkable hydrogen evolution reaction (HER) activity across a range of pH conditions. The heterogeneous Ni–Mo catalyst showed low overpotentials only of 24 and 86, 21 and 60, and 37 and 168 mV to produce a current density of 10 and 100 mA cm−2 (η10 and η100) in alkaline, acidic, and neutral media, respectively, which represents one of the most active catalysts for the HER. The enhanced activity is attributed to the hydrogen spillover effect, where hydrogen atoms migrate between the Ni4Mo alloys and the MoOx matrix, forming hydrogen molybdenum bronze as additional active sites. Additionally, the Ni4Mo facilitated the water dissociation process, which helps the Volmer step in the alkaline/neutral HER. Through electrochemical analysis, in situ Raman spectroscopy, and density functional theory calculations, the fast HER mechanism is elucidated. [ABSTRACT FROM AUTHOR]

Published

2024

11. Hydrogen Spillover Mechanism at the Metal–Metal Interface in Electrocatalytic Hydrogenation.

Author

Li, Yuefei, Li, Linsen, Xu, Shenglin, Cui, Kai, Wang, Tianshuai, Jiang, Zhao, and Li, Jiayuan

Subjects

HYDROGEN as fuel, ENERGY consumption, FORMIC acid, HYDROGENATION, METALS

Abstract

Hydrogen spillover in metal‐supported catalysts can largely enhance electrocatalytic hydrogenation performance and reduce energy consumption. However, its fundamental mechanism, especially at the metal–metal interface, remains further explored, impeding relevant catalyst design. Here, we theoretically profile that a large free energy difference in hydrogen adsorption on two different metals (|ΔGH‐metal(i)−ΔGH‐metal(ii)|) induces a high kinetic barrier to hydrogen spillover between the metals. Minimizing the difference in their d‐band centers (Δϵd) should reduce |ΔGH‐metal(i)−ΔGH‐metal(ii)|, lowering the kinetic barrier to hydrogen spillover for improved electrocatalytic hydrogenation. We demonstrated this concept using copper‐supported ruthenium–platinum alloys with the smallest Δϵd, which delivered record high electrocatalytic nitrate hydrogenation performance, with ammonia production rate of 3.45±0.12 mmol h−1 cm−2 and Faraday efficiency of 99.8±0.2 %, at low energy consumption of 21.4 kWh kgamm−1. Using these catalysts, we further achieve continuous ammonia and formic acid production with a record high‐profit space. [ABSTRACT FROM AUTHOR]

Published

2024

12. Hydrogen Spillover Mechanism at the Metal–Metal Interface in Electrocatalytic Hydrogenation.

Author

Li, Yuefei, Li, Linsen, Xu, Shenglin, Cui, Kai, Wang, Tianshuai, Jiang, Zhao, and Li, Jiayuan

Subjects

HYDROGEN as fuel, ENERGY consumption, FORMIC acid, HYDROGENATION, METALS

Abstract

Hydrogen spillover in metal‐supported catalysts can largely enhance electrocatalytic hydrogenation performance and reduce energy consumption. However, its fundamental mechanism, especially at the metal–metal interface, remains further explored, impeding relevant catalyst design. Here, we theoretically profile that a large free energy difference in hydrogen adsorption on two different metals (|ΔGH‐metal(i)−ΔGH‐metal(ii)|) induces a high kinetic barrier to hydrogen spillover between the metals. Minimizing the difference in their d‐band centers (Δϵd) should reduce |ΔGH‐metal(i)−ΔGH‐metal(ii)|, lowering the kinetic barrier to hydrogen spillover for improved electrocatalytic hydrogenation. We demonstrated this concept using copper‐supported ruthenium–platinum alloys with the smallest Δϵd, which delivered record high electrocatalytic nitrate hydrogenation performance, with ammonia production rate of 3.45±0.12 mmol h−1 cm−2 and Faraday efficiency of 99.8±0.2 %, at low energy consumption of 21.4 kWh kgamm−1. Using these catalysts, we further achieve continuous ammonia and formic acid production with a record high‐profit space. [ABSTRACT FROM AUTHOR]

Published

2024

13. Catalytic Refining Lignin‐Derived Monomers: Seesaw Effect between Nanoparticle and Single‐Atom Pt.

Author

Wang, Weiyan, Li, Shangjian, Qiang, Qian, Wu, Kui, Pan, Xiaoli, Su, Wentao, Cai, Junyang, Shen, Zhigang, Yang, Yunquan, Li, Changzhi, and Zhang, Tao

Subjects

INTERFACIAL reactions, ACTIVATION energy, OXIDATION-reduction reaction, SCISSION (Chemistry), GIBBS' free energy

Abstract

Pt automatically adsorbed on oxygen vacancy of TiO2 via an in situ interfacial redox reaction, resulting in atomically dispersion of Pt on TiO2. In the upgrading of lignin‐derived 4‐propylguaiacol, single‐atom catalyst (SAC) Pt/TiO2−H achieved a conversion of 96.9 % and a demethoxylation selectivity of 93.3 % under 3 MPa H2 at 250 °C for 3 h, markedly different from the performance of nanoparticle counterpart that gave deep deoxygenation selectivity over 99.0 %. The high demethoxylation activity of SAC Pt/TiO2−H is mainly attributed to its weak hydrogen spillover capacity that suppressed the benzene ring hydrogenation and the deep deoxygenation. Additionally, SAC Pt/TiO2−H reduced the energy barrier of CAr−OCH3 bond cleavage and accordingly lowered the Gibbs free energy of the demethoxylation reaction. This facile method could fabricate single‐atom Au, Pd, Ir, and Ru supported on TiO2−H, demonstrating the generality of this strategy for the establishment of a library of SACs. Moreover, SAC exhibited versatile capacity in demethoxylation of different lignin‐derived monomers and high stability. This study showcases the superiority of atomically dispersed metal catalysts for selective demethoxylation reactions and proposes a renewable alternative to fossil‐based 4‐alkylphenols through upgrading of lignin‐derived monomers. [ABSTRACT FROM AUTHOR]

Published

2024

14. Catalytic Refining Lignin‐Derived Monomers: Seesaw Effect between Nanoparticle and Single‐Atom Pt.

Author

Wang, Weiyan, Li, Shangjian, Qiang, Qian, Wu, Kui, Pan, Xiaoli, Su, Wentao, Cai, Junyang, Shen, Zhigang, Yang, Yunquan, Li, Changzhi, and Zhang, Tao

Subjects

INTERFACIAL reactions, ACTIVATION energy, OXIDATION-reduction reaction, SCISSION (Chemistry), GIBBS' free energy

Abstract

Pt automatically adsorbed on oxygen vacancy of TiO2 via an in situ interfacial redox reaction, resulting in atomically dispersion of Pt on TiO2. In the upgrading of lignin‐derived 4‐propylguaiacol, single‐atom catalyst (SAC) Pt/TiO2−H achieved a conversion of 96.9 % and a demethoxylation selectivity of 93.3 % under 3 MPa H2 at 250 °C for 3 h, markedly different from the performance of nanoparticle counterpart that gave deep deoxygenation selectivity over 99.0 %. The high demethoxylation activity of SAC Pt/TiO2−H is mainly attributed to its weak hydrogen spillover capacity that suppressed the benzene ring hydrogenation and the deep deoxygenation. Additionally, SAC Pt/TiO2−H reduced the energy barrier of CAr−OCH3 bond cleavage and accordingly lowered the Gibbs free energy of the demethoxylation reaction. This facile method could fabricate single‐atom Au, Pd, Ir, and Ru supported on TiO2−H, demonstrating the generality of this strategy for the establishment of a library of SACs. Moreover, SAC exhibited versatile capacity in demethoxylation of different lignin‐derived monomers and high stability. This study showcases the superiority of atomically dispersed metal catalysts for selective demethoxylation reactions and proposes a renewable alternative to fossil‐based 4‐alkylphenols through upgrading of lignin‐derived monomers. [ABSTRACT FROM AUTHOR]

Published

2024

15. Interparticle Hydrogen Spillover in Enhanced Catalytic Reactions.

Author

Motokura, Ken

Subjects

METAL catalysts, METHANATION, SUBSTRATES (Materials science), CATALYSIS, CATALYSTS

Abstract

Interparticle hydrogen spillover is the phenomenon of H migration over different catalyst particles, which should be a physical mixture of at least two solid catalysts. In this review, we analyze examples of enhanced catalysis based on interparticle (reverse) hydrogen spillover. Simple physical mixtures of powdered catalysts containing metal catalysts of H2 dissociation/recombination and solid catalysts with active sites for substrate activation significantly enhance catalytic reactions. These reactions include aromatic hydrogenation, CO2 methanation, and the deoxydehydration of polyols, aromatization of lower paraffins, and direct coupling of benzene and alkanes. The acceleration effect and proposed reaction pathway of each example involving interparticle (reverse) hydrogen spillover are summarized. Simple reaction systems comprising physical mixtures of at least two powdery solid catalysts should enable unique catalysis in the future with the aid of interparticle (reverse) hydrogen spillover. [ABSTRACT FROM AUTHOR]

Published

2024

16. Intensifying the Supported Ruthenium Metallic Bond to Boost the Interfacial Hydrogen Spillover Toward pH‐Universal Hydrogen Evolution Catalysis.

Author

Chen, Ya, Liu, Yaoda, Li, Lei, Sakthivel, Thangavel, Guo, Zhixin, and Dai, Zhengfei

Subjects

METALLIC bonds, RUTHENIUM catalysts, INTERFACIAL bonding, HYDROGEN evolution reactions, RUTHENIUM, MASS transfer, CATALYSIS

Abstract

The effectuation of pH‐universal electrocatalysis is highly attractive but still challenging for the hydrogen evolution reaction (HER). It appeals for not only the facilitated electron transport but also the kinetical proton mass transfer. In this study, a via‐hole Ru/MoO2 confined heterostructure is profiled as a metal‐support platform for the electron/mass transfer‐boosted pH‐universal HER studies. It is indicated that the as‐formed Ru─O─Mo bridge can modulate the electronic transport at the interface, and the proton adsorption and transfer are kinetically derived by the intensified metallic Ru─Ru bond. Resultantly, the Ru/MoO2 heterostructure stably attains the Pt‐beyond HER activity with an ultralow overpotential of 9.2 mV at 10 mA cm−2 in 1 m KOH, and also achieves the competitive HER activity and stability in the acidic/neutral electrolytes. Both the experimental and computational results reveal the accelerated HER kinetics is attributable to the intensive mass transfer through the interfacial Ru→MoO2 hydrogen spillover effect. This work opens up the opportunities to rationalize the advanced metal‐support HER electrocatalysts through the interfacial hydrogen spillover effect and metallic bond engineering. [ABSTRACT FROM AUTHOR]

Published

2024

17. Theoretical Investigation of Hydrogen Adsorption and Hydrogen Spillover on Graphene Monolayer-Supported Single Transitional Metal Atoms.

Author

Liu, Xu, Li, Tengfei, Jiang, Zhao, Patel, Bilal, Xu, Donghai, and Guo, Yang

Subjects

GRAPHENE, ATOMS, HYDROGEN storage, DENSITY functional theory, METALS

Abstract

Graphene-based nanostructures loaded with transitional metallic atoms have been identified as promising materials for hydrogen storage. In this study, we investigate the adsorption and spillover of hydrogen on a single transitional metal atom incorporated graphene (TM-Gr) through density functional theory (DFT) calculations. Specifically, we explore the geometric and electronic properties of 20 different TM-Gr structures. Our findings reveal that Y-Gr and Sc-Gr exhibit the most favorable H atom adsorption, while Mn-Gr and Cr-Gr are more suitable for H spillover. Additionally, feature importance analysis highlights that Bader charge accumulated in H atom, C-H bond length, and work function of TM-Gr are the three most important features that are sensitive to the activation energy of H spillover. Overall, this work provides valuable insights for the screening of new materials for hydrogen storage. [ABSTRACT FROM AUTHOR]

Published

2024

18. Research progress of hydrogen storage based on carbon–based materials with the spillover method at room temperature.

Author

Wang, Lei, Guo, Yani, Xu, Qian, Xiong, Jiawei, Chen, Ye, and Nie, Zhengwei

Subjects

HYDROGEN storage, CARBON-based materials, ENERGY futures, TEMPERATURE

Abstract

Hydrogen storage technology is a critical segment for solving future energy problems and is currently an escalating issue for developing our energy economy. In the past two decades, numerous theoretical works and hydrogen storage experiments have been carried out to explore hydrogen storage through the hydrogen spillover method. Hydrogen spillover was found to be an effective method to improve the hydrogen storage performance of carbon – based materials at room temperature. This review mainly addressed the principles of hydrogen spillover, evidence for improving hydrogen storage efficiency, and theoretical studies on the spillover method. In an effort to find some ideas on which materials could be used to store hydrogen at room temperature, we summarized the influencing components of spillover for hydrogen storage from three perspectives: hydrogen storage materials, efficient catalysts, and other factors. Finally, we outlined the current problems and future research directions for hydrogen storage at room temperature and proposed some strategies to address them. [ABSTRACT FROM AUTHOR]

Published

2024

19. Hydrogen spillover bridged dual nano-islands triggered by built-in electric field for efficient and robust alkaline hydrogen evolution at ampere-level current density.

Author

Tong, Kecheng, Xu, Liangliang, Yao, Hanxu, Wang, Xingkun, Zhang, Canhui, Yang, Fan, Chu, Lei, Lee, Jinwoo, Jiang, Heqing, and Huang, Minghua

Subjects

HYDROGEN evolution reactions, ELECTRIC fields, WATER electrolysis, HYDROGEN

Abstract

Employing the alkaline water electrolysis system to generate hydrogen holds great prospects but still poses significant challenges, particularly for the construction of hydrogen evolution reaction (HER) catalysts operating at ampere-level current density. Herein, the unique Ru and RuP2 dual nano-islands are deliberately implanted on N-doped carbon substrate (denoted as Ru-RuP2/NC), in which a built-in electric field (BEF) is spontaneously generated between Ru-RuP2 dual nano-islands driven by their work function difference. Experimental and theoretical results unveil that such constructed BEF could serve as the driving force for triggering fast hydrogen spillover process on bridged Ru-RuP2 dual nano-islands, which could invalidate the inhibitory effect of high hydrogen coverage at ampere-level current density, and synchronously speed up the water dissociation on Ru nano-islands and hydrogen adsorption/desorption on RuP2 nano-islands through hydrogen spillover process. As a result, the Ru-RuP2/NC affords an ultra-low overpotential of 218 mV to achieve 1.0 A·cm−2 along with the superior stability over 1000 h, holding the great promising prospect in practical applications at ampere-level current density. More importantly, this work is the first to advance the scientific understanding of the relationship between the constructed BEF and hydrogen spillover process, which could be enlightening for the rational design of the cost-effective alkaline HER catalysts at ampere-level current density. [ABSTRACT FROM AUTHOR]

Published

2024

20. Achieving Negatively Charged Pt Single Atoms on Amorphous Ni(OH)2 Nanosheets with Promoted Hydrogen Absorption in Hydrogen Evolution.

Author

Liu, Yue, Liu, Gui, Chen, Xiangyu, Xue, Chuang, Sun, Mingke, Liu, Yifei, Kang, Jianxin, Sun, Xiujuan, and Guo, Lin

Subjects

OXYGEN evolution reactions, HYDROGEN evolution reactions, ATOMS, HYDROGEN atom, CATALYTIC activity, ELECTRON configuration, ELECTROLYTIC reduction

Abstract

Highlights: Pt–Ni bonded Pt single-atom (SA) catalyst, rather than classic Pt–O bonded SA catalyst, was successfully constructed. The electronic states of Pt SA catalyst were deeply regulated and negatively charged Ptδ− was realized. Pt–Ni bonded Pt SA catalyst-enhanced absorbability for activated hydrogen atoms and promoted hydrogen absorption. Single-atom (SA) catalysts with nearly 100% atom utilization have been widely employed in electrolysis for decades, due to the outperforming catalytic activity and selectivity. However, most of the reported SA catalysts are fixed through the strong bonding between the dispersed single metallic atoms with nonmetallic atoms of the substrates, which greatly limits the controllable regulation of electrocatalytic activity of SA catalysts. In this work, Pt–Ni bonded Pt SA catalyst with adjustable electronic states was successfully constructed through a controllable electrochemical reduction on the coordination unsaturated amorphous Ni(OH)2 nanosheet arrays. Based on the X-ray absorption fine structure analysis and first-principles calculations, Pt SA was bonded with Ni sites of amorphous Ni(OH)2, rather than conventional O sites, resulting in negatively charged Ptδ−. In situ Raman spectroscopy revealed that the changed configuration and electronic states greatly enhanced absorbability for activated hydrogen atoms, which were the essential intermediate for alkaline hydrogen evolution reaction. The hydrogen spillover process was revealed from amorphous Ni(OH)2 that effectively cleave the H–O–H bond of H2O and produce H atom to the Pt SA sites, leading to a low overpotential of 48 mV in alkaline electrolyte at −1000 mA cm−2 mg−1Pt, evidently better than commercial Pt/C catalysts. This work provided new strategy for the controllable modulation of the local structure of SA catalysts and the systematic regulation of the electronic states. [ABSTRACT FROM AUTHOR]

Published

2024

21. Cobalt Single‐Atom Reverse Hydrogen Spillover for Efficient Electrochemical Water Dissociation and Dechlorination.

Author

Zheng, Qian, Xu, Hengyue, Yao, Yancai, Dai, Jie, Wang, Jiaxian, Hou, Wei, Zhao, Long, Zou, Xingyue, Zhan, Guangming, Wang, Ruizhao, Wang, Kaiyuan, and Zhang, Lizhi

Subjects

FOAM, ATOMIC hydrogen, HYDROGEN, COBALT, TITANIUM oxides, ENERGY consumption, ELECTRODIALYSIS, HYDROGEN as fuel

Abstract

Efficient water dissociation to atomic hydrogen (H*) with restrained recombination of H* is crucial for improving the H* utilization for electrochemical dechlorination, but is currently limited by the lack of feasible electrodes. Herein, we developed a monolithic single‐atom electrode with Co single atoms anchored on the inherent oxide layer of titanium foam (Co1−TiOx/Ti), which can efficiently dissociate water into H* and simultaneously inhibit the recombination of H*, by taking advantage of the single‐atom reverse hydrogen spillover effect. Experimental and theoretical calculations demonstrated that H* could be rapidly generated on the oxide layer of titanium foam, and then overflowed to the adjacent Co single atom for the reductive dechlorination. Using chloramphenicol as a proof‐of‐concept verification, the resulting Co1−TiOx/Ti monolithic electrode exhibited an unprecedented performance with almost 100 % dechlorination at −1.0 V, far superior to that of traditional indirect reduction‐driven commercial Pd/C (52 %) and direct reduction‐driven Co1−N−C (44 %). Moreover, its dechlorination rate constant of 1.64 h−1 was 4.3 and 8.6 times more active than those of Pd/C (0.38 h−1) and Co1−N−C (0.19 h−1), respectively. Our research sheds light on the rational design of hydrogen spillover‐related electrocatalysts to simultaneously improve the H* generation, transfer, and utilization for environmental and energy applications. [ABSTRACT FROM AUTHOR]

Published

2024

22. Cobalt Single‐Atom Reverse Hydrogen Spillover for Efficient Electrochemical Water Dissociation and Dechlorination.

Author

Zheng, Qian, Xu, Hengyue, Yao, Yancai, Dai, Jie, Wang, Jiaxian, Hou, Wei, Zhao, Long, Zou, Xingyue, Zhan, Guangming, Wang, Ruizhao, Wang, Kaiyuan, and Zhang, Lizhi

Subjects

FOAM, ATOMIC hydrogen, HYDROGEN, COBALT, TITANIUM oxides, ENERGY consumption, ELECTRODIALYSIS, HYDROGEN as fuel

Abstract

Efficient water dissociation to atomic hydrogen (H*) with restrained recombination of H* is crucial for improving the H* utilization for electrochemical dechlorination, but is currently limited by the lack of feasible electrodes. Herein, we developed a monolithic single‐atom electrode with Co single atoms anchored on the inherent oxide layer of titanium foam (Co1−TiOx/Ti), which can efficiently dissociate water into H* and simultaneously inhibit the recombination of H*, by taking advantage of the single‐atom reverse hydrogen spillover effect. Experimental and theoretical calculations demonstrated that H* could be rapidly generated on the oxide layer of titanium foam, and then overflowed to the adjacent Co single atom for the reductive dechlorination. Using chloramphenicol as a proof‐of‐concept verification, the resulting Co1−TiOx/Ti monolithic electrode exhibited an unprecedented performance with almost 100 % dechlorination at −1.0 V, far superior to that of traditional indirect reduction‐driven commercial Pd/C (52 %) and direct reduction‐driven Co1−N−C (44 %). Moreover, its dechlorination rate constant of 1.64 h−1 was 4.3 and 8.6 times more active than those of Pd/C (0.38 h−1) and Co1−N−C (0.19 h−1), respectively. Our research sheds light on the rational design of hydrogen spillover‐related electrocatalysts to simultaneously improve the H* generation, transfer, and utilization for environmental and energy applications. [ABSTRACT FROM AUTHOR]

Published

2024

23. Boosting the Electroactivity of Porous Ni2P/Pd6P Nanorods for Nitrate to Ammonia Through Hydrogen Spillover Effect.

Author

Zhang, Xiaoyu, Wang, Jiayi, Zong, Kai, Yang, Yi, Wang, Xin, and Chen, Zhongwei

Subjects

NANORODS, HABER-Bosch process, DENITRIFICATION, DENSITY functional theory, NITRATES, HYDROGEN

Abstract

In contrast to the energy‐intensive Haber‐Bosch process, the electroreduction of nitrate to ammonia presents a promising alternative. In this work, the Ni2P/Pd6P nanorods (named NiPdP‐NR) are successfully synthesized by using a simple phosphating process with NiIIPdII‐dimethylglyoxime complex (NiIIPdII‐DMG) nanorods as the precursor. Density functional theory calculations and electrochemical experiments prove that the introduction of Pd facilitates hydrogen spillover from Pd to Ni2P modulates the surface electronic structures, and therefore improves the catalytic kinetics of nitrate reduction ultimately. According to the dynamic experiment, the as‐prepared NiPdP‐NR shows high nitrate conversion efficiency (90.6%), selectivity of NH3 (93.4%), high Faradic efficiency (92.6%), and NH3 yield rate (0.908 mmol h−1 mgcat−1) for the nitrate reduction. [ABSTRACT FROM AUTHOR]

Published

2024

24. Tandem Electrocatalytic Alkyne Semihydrogenation over Bicomponent Catalysts through Hydrogen Spillover.

Author

Tan, Qiang, Li, Linsen, Li, Yuefei, Jiang, Zhao, Ma, Yuanyuan, Qu, Yongquan, and Li, Jiayuan

Subjects

ATOMIC hydrogen, CATALYSTS, HYDROGEN, ENERGY consumption, INTERSTITIAL hydrogen generation, COPPER

Abstract

Electrocatalytic alkyne semihydrogenation under mild conditions is a more attractive approach for alkene production than industrial routes but suffers from either low production efficiency or high energy consumption. Here, we describe a tandem catalytic concept that overcomes these challenges. Component (i), which can trap hydrogen effectively, is partnered with component (ii), which can readily release hydrogen for hydrogenation, to enable efficient generation of active hydrogen on component (i) at low overpotentials and timely (i)‐to‐(ii) hydrogen spillover and facile desorptive hydrogenation on component (ii). We examine this concept over bicomponent palladium‐copper catalysts for the production of representative 2‐methyl‐3‐butene‐2‐ol (MBE) from 2‐methyl‐3‐butyne‐2‐ol (MBY) and achieve a record high MBE production rate of 1.44 mmol h−1 cm−2 and a Faraday efficiency of ~88.8 % at a low energy consumption of 1.26 kWh kgMBE−1. With these catalysts, we further achieve 60 h continuous production of MBE with record high profit space. [ABSTRACT FROM AUTHOR]

Published

2024

25. Tandem Electrocatalytic Alkyne Semihydrogenation over Bicomponent Catalysts through Hydrogen Spillover.

Author

Tan, Qiang, Li, Linsen, Li, Yuefei, Jiang, Zhao, Ma, Yuanyuan, Qu, Yongquan, and Li, Jiayuan

Subjects

ATOMIC hydrogen, CATALYSTS, HYDROGEN, ENERGY consumption, INTERSTITIAL hydrogen generation, COPPER

Abstract

Electrocatalytic alkyne semihydrogenation under mild conditions is a more attractive approach for alkene production than industrial routes but suffers from either low production efficiency or high energy consumption. Here, we describe a tandem catalytic concept that overcomes these challenges. Component (i), which can trap hydrogen effectively, is partnered with component (ii), which can readily release hydrogen for hydrogenation, to enable efficient generation of active hydrogen on component (i) at low overpotentials and timely (i)‐to‐(ii) hydrogen spillover and facile desorptive hydrogenation on component (ii). We examine this concept over bicomponent palladium‐copper catalysts for the production of representative 2‐methyl‐3‐butene‐2‐ol (MBE) from 2‐methyl‐3‐butyne‐2‐ol (MBY) and achieve a record high MBE production rate of 1.44 mmol h−1 cm−2 and a Faraday efficiency of ~88.8 % at a low energy consumption of 1.26 kWh kgMBE−1. With these catalysts, we further achieve 60 h continuous production of MBE with record high profit space. [ABSTRACT FROM AUTHOR]

Published

2024

26. Diluting the Resistance of Built‐in Electric Fields in Oxygen Vacancy‐enriched Ru/NiMoO4‐x for Enhanced Hydrogen Spillover in Alkaline Seawater Splitting.

Author

Liu, Xiaobin, Wang, Xuanyi, Li, Kun, Tang, Junheng, Zhu, Jiawei, Chi, Jingqi, Lai, Jianping, and Wang, Lei

Abstract

Recently, hydrogen spillover based binary (HSBB) catalysts have received widespread attention due to the sufficiently utilized reaction sites. However, the specific regulation mechanism of spillover intensity is still unclear. Herein, we have fabricated oxygen vacancies enriched Ru/NiMoO4‐x to investigate the internal relationship between electron supply and mechanism of hydrogen spillover enhancement. The DFT calculations cooperate with in situ Raman spectrum to uncover that the H* spillover from NiMoO4‐x to Ru. Meanwhile, oxygen vacancies weakened the electron supply from Ru to NiMoO4‐x, which contributes to dilute the resistance of built‐in electric field (BEF) for hydrogen spillover. In addition, the higher ion concentration in electrolyte will promote the H* adsorption step obviously, which is demonstrated by in situ EIS tests. As a result, the Ru/NiMoO4‐x exhibits a low overpotential of 206 mV at 3.0 A cm−2, a small Tafel slope of 28.8 mV dec−1, and an excellent durability of 550 h at the current density of 0.5 A cm−2 for HER in 1.0 M KOH seawater. [ABSTRACT FROM AUTHOR]

Published

2024

27. Diluting the Resistance of Built‐in Electric Fields in Oxygen Vacancy‐enriched Ru/NiMoO4‐x for Enhanced Hydrogen Spillover in Alkaline Seawater Splitting.

Author

Liu, Xiaobin, Wang, Xuanyi, Li, Kun, Tang, Junheng, Zhu, Jiawei, Chi, Jingqi, Lai, Jianping, and Wang, Lei

Subjects

ELECTRIC resistance, ELECTRIC fields, SEAWATER, HYDROGEN, RAMAN spectroscopy

Abstract

Recently, hydrogen spillover based binary (HSBB) catalysts have received widespread attention due to the sufficiently utilized reaction sites. However, the specific regulation mechanism of spillover intensity is still unclear. Herein, we have fabricated oxygen vacancies enriched Ru/NiMoO4‐x to investigate the internal relationship between electron supply and mechanism of hydrogen spillover enhancement. The DFT calculations cooperate with in situ Raman spectrum to uncover that the H* spillover from NiMoO4‐x to Ru. Meanwhile, oxygen vacancies weakened the electron supply from Ru to NiMoO4‐x, which contributes to dilute the resistance of built‐in electric field (BEF) for hydrogen spillover. In addition, the higher ion concentration in electrolyte will promote the H* adsorption step obviously, which is demonstrated by in situ EIS tests. As a result, the Ru/NiMoO4‐x exhibits a low overpotential of 206 mV at 3.0 A cm−2, a small Tafel slope of 28.8 mV dec−1, and an excellent durability of 550 h at the current density of 0.5 A cm−2 for HER in 1.0 M KOH seawater. [ABSTRACT FROM AUTHOR]

Published

2024

28. Indium‐based Catalysts for CO2 Hydrogenation to Methanol: Key Aspects for Catalytic Performance.

Author

Wesner, Anne, Kampe, Philipp, Herrmann, Nick, Eller, Sebastian, Ruhmlieb, Charlotte, and Albert, Jakob

Subjects

HYDROGENATION, CATALYSTS, CATALYST supports, INDUSTRIAL chemistry, METHANOL as fuel, CLIMATE change mitigation, METHANOL

Abstract

CO2 hydrogenation utilizing sustainably produced hydrogen and CO2 derived from industrial exhaust gas represents a pivotal technology for chemical energy storage and climate change mitigation. This work aims to identify the best combination of catalyst support, synthesis method and promotor for In2O3/ZrO2 catalysts in a typical fixed‐bed configuration. Intense characterization using ICP‐OES, XRD, XPS, N2‐physisorption, CO2‐TPD, H2‐TPR and SEM‐EDX provide molecular insights into the different effects caused by various synthesis methods and doping elements. Doping the most promising In2O3/ZrO2 (M‐SG) catalyst with 0.7 wt. % NiO by wetness impregnation using an ethanol/water mixture as a solvent, an increased methanol production rate of 0.497 gMeOH ⋅gcat1 ${{{\rm { \hskip0.17em}}{\rm { g}}}_{{\rm { cat}}}^{{\rm { 1}}}}$ ⋅ h−1 could already be achieved at 250 °C. Hereby, the low amount of highly dispersed NiO promotes H2 activation via hydrogen spillover, leading to sustained catalytic activity for 100 hours of time‐on‐stream. [ABSTRACT FROM AUTHOR]

Published

2023

29. Hydrogenation Catalysis by Hydrogen Spillover on Platinum‐Functionalized Heterogeneous Boronic Acid‐Polyoxometalates.

Author

Li, Shujun, Ma, Yubin, Zhao, Yue, Liu, Rongji, Zhao, Yupeng, Dai, Xusheng, Ma, Nana, Streb, Carsten, and Chen, Xuenian

Subjects

PLATINUM nanoparticles, CATALYTIC hydrogenation, HYDROGENATION, BORONIC acids, CATALYSIS

Abstract

The activation of molecular hydrogen is a key process in catalysis. Here, we demonstrate how polyoxometalate (POM)‐based heterogeneous compounds functionalized with Platinum particles activate H2 by synergism between a hydrogen spillover mechanism and electron‐proton transfer by the POM. This interplay facilitates the selective catalytic reduction of olefins and nitroarenes with high functional group tolerance. A family of polyoxotungstates covalently functionalized with boronic acids is reported. In the solid‐state, the compounds are held together by non‐covalent interactions (π–π stacking and hydrogen bonding). The resulting heterogeneous nanoscale particles form stable colloidal dispersions in acetonitrile and can be surface‐functionalized with platinum nanoparticles by in situ photoreduction. The resulting materials show excellent catalytic activity in hydrogenation of olefins and nitrobenzene derivatives under mild conditions (1 bar H2 and room temperature). [ABSTRACT FROM AUTHOR]

Published

2023

30. Hydrogenation Catalysis by Hydrogen Spillover on Platinum‐Functionalized Heterogeneous Boronic Acid‐Polyoxometalates.

Author

Li, Shujun, Ma, Yubin, Zhao, Yue, Liu, Rongji, Zhao, Yupeng, Dai, Xusheng, Ma, Nana, Streb, Carsten, and Chen, Xuenian

Subjects

PLATINUM nanoparticles, CATALYTIC hydrogenation, HYDROGENATION, BORONIC acids, CATALYSIS

Abstract

The activation of molecular hydrogen is a key process in catalysis. Here, we demonstrate how polyoxometalate (POM)‐based heterogeneous compounds functionalized with Platinum particles activate H2 by synergism between a hydrogen spillover mechanism and electron‐proton transfer by the POM. This interplay facilitates the selective catalytic reduction of olefins and nitroarenes with high functional group tolerance. A family of polyoxotungstates covalently functionalized with boronic acids is reported. In the solid‐state, the compounds are held together by non‐covalent interactions (π–π stacking and hydrogen bonding). The resulting heterogeneous nanoscale particles form stable colloidal dispersions in acetonitrile and can be surface‐functionalized with platinum nanoparticles by in situ photoreduction. The resulting materials show excellent catalytic activity in hydrogenation of olefins and nitrobenzene derivatives under mild conditions (1 bar H2 and room temperature). [ABSTRACT FROM AUTHOR]

Published

2023

31. Enhanced Catalytic Selectivity in Hydrogenation of Substituted Nitroarenes through Hydrogen Spillover over Sodalite Zeolite Encapsulated Platinum Clusters.

Author

Yang, Ganjun, He, Yanan, Zhang, Chengxi, Sun, Zongyu, Han, Mengxi, Peng, Pai, Yue, Yaning, Liu, Hongxia, Liu, Lei, Chen, Junwen, Bai, Licheng, and Chen, Qiang

Subjects

CATALYTIC hydrogenation, SODALITE, NITROAROMATIC compounds, PLATINUM, ZEOLITE catalysts, HYDROGEN, ZEOLITES

Abstract

Herein, we reported that the platinum (Pt) clusters encapsulated into sodalite (SOD) zeolite as catalyst exhibited 100 % selectivity at 100 % conversion in the selective hydrogenation of p‐chloronitrobenzene to p‐chloroaniline via hydrogen spillover. The direct interaction between p‐chloronitrobenzene and encapsulated Pt was prevented by the shape selectivity of SOD zeolite, reactants were thereby adsorbed onto zeolite outer surface to facilitate the hydrogenation proceeding by hydrogen spillover process. The further kinetic study and DFT calculation showed the excellent catalytic selectivity was ascribed to the much faster rate of hydrogenation of adsorbed nitro group than that of adsorbed C−Cl group. [ABSTRACT FROM AUTHOR]

Published

2023

32. Construction of pH-universal hydrogen evolution freeway in MoO3-MoNi4@Cu core–shell nanowires via synergetic electronic and geometric effect.

Author

Chen, Xiaodong, Cao, Shoufu, Lin, Xiaojing, Wei, Xiaofei, Wang, Zhaojie, Chen, Hongyu, Hao, Chengcheng, Liu, Siyuan, Wei, Shuxian, Sun, Daofeng, and Lu, Xiaoqing

Subjects

POLAR effects (Chemistry), HYDROGEN evolution reactions, NANOWIRES, MOLYBDENUM alloys, NICKEL alloys

Abstract

Both the adsorption/dissociation of water molecules and hydrogen intermediate (H*) are the major limitations to hydrogen evolution reaction (HER). Herein, the modulation of electronic structure and geometric configuration are combined to design one-dimensional electrocatalyst with outstanding HER activity in a wide pH range. The catalyst was composed of molybdenum trioxide doped molybdenum nickel alloy supported by copper nanowires (MoO3-MoNi4@Cu NWs). As revealed by the experimental characterizations and theoretical calculations, Cu NWs act as the electron donator to MoNi4, resulting in up shift of the d-band center in MoNi4, thus expediting H2O adsorption and dissociation. Moreover, the introduction of amorphous MoO3 sets up a unique geometric configuration on MoNi4 for the accelerated H* transfer via hydrogen-bond and hydrogen spillover. This work provides a synergetic route for constructing HER freeway and promotes further investigations on more versatile electrocatalysis involving H2O or H*. [ABSTRACT FROM AUTHOR]

Published

2023

33. Hydrogen Spillover in Tungsten Oxide Bronzes as Observed by Broadband Neutron Spectroscopy.

Author

Lalik, Erwin, Parker, Stewart F., Irvine, Gavin, da Silva, Ivan, Gutmann, Matthias Josef, Romanelli, Giovanni, Drużbicki, Kacper, Kosydar, Robert, and Krzystyniak, Matthew

Subjects

NEUTRON spectroscopy, TUNGSTEN oxides, TUNGSTEN bronze, ATOMIC hydrogen, COMPTON scattering, MOMENTUM distributions, BROADBAND dielectric spectroscopy, INELASTIC neutron scattering, PROTON transfer reactions

Abstract

Hydrogen spillover is an elusive process, and its characterization, using experimental probes and ab initio modeling, poses a serious challenge. In this work, the nuclear quantum dynamics of hydrogen in a palladium-decorated cubic polymorph of tungsten oxide, Pd/cWO3, are characterized by the technique of neutron Compton scattering augmented by ab initio harmonic lattice modeling. The deeply penetrating nature of the neutron scattering process, the lack of spectroscopic selection rules, the inherent high sensitivity to hydrogen, the high energy and momentum resolution for hydrogen, and the mass selectivity of the technique render the neutron Compton scattering a very potent and unique tool for investigating the local dynamics of hydrogen species in bulk matrices. The total neutron Compton scattering response of hydrogen is described in terms of the hydrogen momentum distribution. The distribution is deconvoluted under the assumption of three pools of hydrogen with distinctly different nuclear quantum dynamical behavior: (i) hydrogen-terminated beta-palladium hydride, (ii) hydrogen in acid centers (OH+ groups) on the surface of the cubic phase of tungsten oxide, and (iii) quasi-free atomic hydrogen inside the saturated hydrogen bronze resulting from the spillover process. The ab initio modeling of lattice dynamics yields theoretical predictions for the values of the widths of proton momentum distributions in the first two hydrogen pools, which allows for obtaining the contribution and the width of the momentum distribution of the quasi-free atomic hydrogen resulting from the hydrogen spillover process. The analysis reveals that the local binding strength of the quasi-free hydrogen is characterized by the values of nuclear momentum distribution width, nuclear kinetic energy, and force constant of the underlying potential of the mean force close to those of free, unconstrained hydrogen atomic species in a gas of non-interacting particles described by the Maxwell–Boltzmann distribution. Moreover, this picture of the local dynamics of the quasi-free hydrogen is consistent with the proton polaron model of hydrogen-induced coloration of bulk hydrogenated WO3. [ABSTRACT FROM AUTHOR]

Published

2023

34. Phenol Hydrogenation to Cyclohexanol Catalysed by Palladium Supported on CuO/CeO2.

Author

Kasabe, Mirabai M., Kotkar, Vaibhav R., Dongare, Mohan K., and Umbarkar, Shubhangi B.

Subjects

PHENOL, PHENOXIDES, PALLADIUM, HYDROGENATION, WATER pressure

Abstract

Hydrogenation of phenol to cyclohexanone/cyclohexanol is an important reaction in production of nylon‐6, nylon‐66 and in petroleum industry. Liquid phase phenol hydrogenation over Pd‐CuO/CeO2 was carried out under mild conditions. Palladium impregnated over CuO/CeO2 synthesized by co‐precipitation method showed excellent catalytic activity for phenol hydrogenation (99% conversion with 80% cyclohexanol yield) at 90 °C and 10 bar H2 pressure in water. Commercial 10%Pd/C showed only 8% phenol conversion under identical conditions. The detailed characterization revealed significant improvement in surface area of ceria after addition of CuO and decrease in crystallite size with creation of defects in CeO2 lattice. XPS analysis showed Pd loading on CuO/CeO2 to cause hydrogen spillover on the surface leading to increase in the oxygen vacancies. The interaction of phenol with catalyst surface studied by detailed FTIR analysis, revealed activation of phenol on oxygen vacancy of ceria as phenoxide ion with perpendicular orientation of aromatic ring on catalyst surface. [ABSTRACT FROM AUTHOR]

Published

2023

35. Iodine‐modified Pt nanoparticles accelerate the hydrogenative ring‐opening of furfurals to linear alcohols.

Author

Zhang, Likang, Li, Xiang, Wang, Jun, Zeng, Zheling, Yang, Weiran, Deng, Shuguang, and Deng, Qiang

Subjects

TETRAHYDROFURAN synthesis, BIFUNCTIONAL catalysis, GLYCOLS, CHEMICAL synthesis, CATALYTIC activity, IODINE, PRECIOUS metals

Abstract

The hydrogenative ring‐opening of furfurals (furfural and 5‐methylfurfural) to linear diols (1,4‐pentanediol and 2,5‐hexanediol) is of great significance for bioderived fine chemical synthesis. Unfortunately, the catalytic activity and selectivity are unsatisfactory because of the interference of various side reactions, such as overhydrogenation to tetrahydrofurans. Herein, the preparation of an iodine (I) modified Pt‐based catalyst with abundant Pt‐I pairs is reported for the first time and shows high catalytic efficiency for linear diol synthesis with a yield of 80%–90% via the hydrogenative ring‐opening route, whereas bare Pt counterpart only shows tetrahydrofuran synthesis via the overhydrogenation route. The catalytic reaction mechanism shows the in‐situ hydrogen spillover‐promoted H−‐Pt‐I‐H+ pairs not only supply hydrogenation sites for the C=O hydrogenation step but also provide Brønsted acidic sites for the ring‐opening step. This work presents a feasible and convenient strategy for bifunctional catalysis with powerful linear diol synthesis over iodine‐modified noble metals. [ABSTRACT FROM AUTHOR]

Published

2023

36. Density Functional Calculations of the Sequential Adsorption of Hydrogen on Single Atom and Small Clusters of Pd and Pt Supported on Au(111).

Author

Meléndez-Rivera, Joshua and Santana, Juan A.

Abstract

We have used density functional theory calculations to study the sequential adsorption of hydrogen on Pd and Pt atomic site catalysts such as single-atom alloy catalysts (SAAC), single-atom catalysts (SAC), and single cluster catalysts (SCC) on Au(111). The results show that Pd systems tend to have near-zero free energy of hydrogen adsorption ( Δ G H ads ≈ 0 ) under various coverage conditions of adsorbed hydrogen. In the case of Pt systems, Δ G H ads ≈ 0 only at high coverage conditions of adsorbed hydrogen. Such differences come from the preference of hydrogen for high-coordination and low-coordination sites on Pd and Pt, respectively. The low coordination of hydrogen results in multiple adsorption sites with Δ G H ads ≈ 0 in SCC of Pt/Au. These results can help to understand the different catalytic properties of Pd/Au and Pt/Au. [ABSTRACT FROM AUTHOR]

Published

2023

37. Intensifying Hydrogen Spillover for Boosting Electrocatalytic Hydrogen Evolution Reaction.

Author

Xu, Hui, Li, Junru, and Chu, Xianxu

Subjects

HYDROGEN evolution reactions, HYDROGEN content of metals, HYDROGEN, HYDROGEN production, WATER electrolysis

Abstract

Hydrogen spillover has attracted increasing interests in the field of electrocatalytic hydrogen evolution reaction (HER) in recent years because of their distinct reaction mechanism and beneficial terms for simultaneously weakening the strong hydrogen adsorption on metal and strengthening the weak hydrogen adsorption on support. By taking advantageous merits of efficient hydrogen transfer, hydrogen spillover‐based binary catalysts have been widely investigated, which paves a new way for boosting the development of hydrogen production by water electrolysis. In this paper, we summarize the recent progress of this interesting field by focusing on the advanced strategies for intensifying the hydrogen spillover towards HER. In addition, the challenging issues and some perspective insights in the future development of hydrogen spillover‐based electrocatalysts are also systematically discussed. [ABSTRACT FROM AUTHOR]

Published

2023

38. Insights into the active sites of dual‐zone synergistic catalysts for semi‐hydrogenation under hydrogen spillover.

Author

Wang, Shuai, Lv, Yipin, Wang, Xilong, Gao, Daowei, Duan, Aijun, Zhao, Huaiqing, Zheng, Peng, and Chen, Guozhu

Subjects

ETHYNYL benzene, GOLD nanoparticles, HYDROGEN atom, HYDROGEN, CATALYSTS, PLATINUM catalysts

Abstract

A well‐defined catalyst with platinum (Pt) and gold (Au) encapsulated in micropore and mesopore of micro‐mesoporous zeolite (Pt‐Au/TMSN), respectively, was designed to investigate the original active sites of semi‐hydrogenation. Specifically, hydrogen molecules are dissociated on Pt nanoclusters (NCs) to form hydrogen atoms that migrate to the surfaces of TMSN zeolite and Au nanoparticles (NPs) through hydrogen spillover effect. The characterization and catalytic results demonstrate that the Au NPs and zeolite surface are both identified as the semi‐hydrogenation sites. Especially, the Au active site with low adsorption ability of alkene possesses preferable selectivity in the semi‐hydrogenation of phenylacetylene and 1,5‐cyclooctadiene. Noteworthy, the Pt‐Au/TMSN exhibits higher selectivity of phenylethylene and cyclooctene than Pt/TMSN, as well as higher turnover frequency than Au/MSN. This work creates an effective regulation strategy of active sites working with a tandem mechanism for improving the semi‐hydrogenation performance. [ABSTRACT FROM AUTHOR]

Published

2023

39. Heterogeneous Hydrogenation with Hydrogen Spillover Enabled by Nitrogen Vacancies on Boron Nitride‐Supported Pd Nanoparticles.

Author

Zhang, Yazhou, Zhan, Shaoqi, Liu, Kunlong, Qiao, Mengfei, Liu, Ning, Qin, Ruixuan, Xiao, Liangping, You, Pengyao, Jing, Wentong, and Zheng, Nanfeng

Subjects

HYDROGENATION, BORON nitride, CARBON monoxide poisoning, BORON, HYDROGEN

Abstract

Heterogeneous hydrogenation with hydrogen spillover has been demonstrated as an effective route to achieve high selectivity towards target products. More effort should be paid to understand the complicated correlation between the nature of supports and hydrogenation involving hydrogen spillover. Herein, we report the development of the hydrogenation system of hexagonal boron nitride (h‐BN)‐supported Pd nanoparticles for the hydrogenation of aldehydes/ketones to alcohols with hydrogen spillover. Nitrogen vacancies in h‐BN determine the feasibility of hydrogen spillover from Pd to h‐BN. The hydrogenation of aldehydes/ketones with hydrogen spillover from Pd proceeds on nitrogen vacancies on h‐BN. The weak adsorption of alcohols to h‐BN inhibits the deep hydrogenation of aldehydes/ketones, thus leading to high catalytic selectivity to alcohols. Moreover, the hydrogen spillover‐based hydrogenation mechanism makes the catalyst system exhibit a high tolerance to CO poisoning. [ABSTRACT FROM AUTHOR]

Published

2023

40. Hydrogen Spillover‐Promoted Hydrogen Evolution onto Copper.

Author

Xing, Liwen, Liu, Yan, Liu, Yaqi, Wu, Ke, and Ji, Yongjun

Subjects

HYDROGEN evolution reactions, HYDROGEN as fuel, HYDROGEN, PRECIOUS metals, COPPER, BINDING energy

Abstract

Currently, green hydrogen harvesting from electrochemical water splitting is overly reliant on noble metals with high catalytic activity but low natural abundance and high cost. As one of potential earth‐abundant alternatives, copper, however, displays a poor hydrogen evolving capability, mainly due to inherently a weak hydrogen binding energy (HBE). It poses a substantial restriction to metallic Cu alone serving as primary active sites for high‐performance hydrogen evolution. Thanks to the presence of hydrogen spillover that was often overlooked during the electrocatalysis, the hydrogen evolution in a nonacidic electrolyte can be accelerated by the recombination desorption of adsorbed hydrogen over Cu with a weak HBE. Here, we concisely highlighted this promotion effect of secondary active Cu on electrocatalytic hydrogen evolution and eagerly expected to extend hydrogen spillover effects to the advance of multi‐site electrocatalytic systems. [ABSTRACT FROM AUTHOR]

Published

2023

41. Heterogeneous Hydrogenation with Hydrogen Spillover Enabled by Nitrogen Vacancies on Boron Nitride‐Supported Pd Nanoparticles.

Author

Zhang, Yazhou, Zhan, Shaoqi, Liu, Kunlong, Qiao, Mengfei, Liu, Ning, Qin, Ruixuan, Xiao, Liangping, You, Pengyao, Jing, Wentong, and Zheng, Nanfeng

Subjects

HYDROGENATION, BORON nitride, CARBON monoxide poisoning, BORON, HYDROGEN

Abstract

Heterogeneous hydrogenation with hydrogen spillover has been demonstrated as an effective route to achieve high selectivity towards target products. More effort should be paid to understand the complicated correlation between the nature of supports and hydrogenation involving hydrogen spillover. Herein, we report the development of the hydrogenation system of hexagonal boron nitride (h‐BN)‐supported Pd nanoparticles for the hydrogenation of aldehydes/ketones to alcohols with hydrogen spillover. Nitrogen vacancies in h‐BN determine the feasibility of hydrogen spillover from Pd to h‐BN. The hydrogenation of aldehydes/ketones with hydrogen spillover from Pd proceeds on nitrogen vacancies on h‐BN. The weak adsorption of alcohols to h‐BN inhibits the deep hydrogenation of aldehydes/ketones, thus leading to high catalytic selectivity to alcohols. Moreover, the hydrogen spillover‐based hydrogenation mechanism makes the catalyst system exhibit a high tolerance to CO poisoning. [ABSTRACT FROM AUTHOR]

Published

2023

42. Redrawing HER Volcano with Interfacial Processes—The Role of Hydrogen Spillover in Boosting H 2 Evolution in Alkaline Media.

Author

Gutić, Sanjin J., Metarapi, Dino, Jovanović, Aleksandar Z., Gebremariam, Goitom K., Dobrota, Ana S., Nedić Vasiljević, Bojana, and Pašti, Igor A.

Subjects

HYDROGEN as fuel, HYDROGEN production, HYDROGEN, ENERGY shortages, METALLIC oxides, FOSSIL fuels, VOLCANOES, HYDROGEN evolution reactions, GRAPHENE oxide

Abstract

The requirements for the efficient replacement of fossil fuel, combined with the growing energy crisis, places focus on hydrogen production. Efficient and cost-effective electrocatalysts are needed for H2 production, and novel strategies for their discovery must be developed. Here, we utilized Kinetic Monte Carlo (KMC) simulations to demonstrate that hydrogen evolution reaction (HER) can be boosted via hydrogen spillover to the support when the catalyst surface is largely covered by adsorbed hydrogen under operating conditions. Based on the insights from KMC, we synthesized a series of reduced graphene-oxide-supported catalysts and compared their activities towards HER in alkaline media with that of corresponding pure metals. For Ag, Au, and Zn, the support effect is negative, but for Pt, Pd, Fe, Co, and Ni, the presence of the support enhances HER activity. The HER volcano, constructed using calculated hydrogen binding energies and measured HER activities, shows a positive shift of the strong binding branch. This work demonstrates the possibilities of metal–support interface engineering for producing effective HER catalysts and provides general guidelines for choosing novel catalyst–support combinations for electrocatalytic hydrogen production. [ABSTRACT FROM AUTHOR]

Published

2023

43. Hydrogen spillover in nonreducible oxides: Mechanism and catalytic utilization.

Author

Lee, Songhyun, Kim, Hyungjun, Ryoo, Ryong, Park, Jeong Young, and Choi, Minkee

Abstract

Hydrogen (H) spillover in nonreducible oxides such as zeolites and Al2O3 has been a highly controversial phenomenon in heterogeneous catalysis. Since industrial catalysts are predominantly prepared using these materials as supports, it is important to understand the mechanism and catalytic functions of H spillover on their surfaces. In the past decade, fundamental studies on zeolite-encapsulated metal catalysts have revealed that H spillover and reverse spillover can be utilized in the design of hydrogenation and dehydrogenation catalysts with improved properties. Both experimental and theoretical studies have indicated that H spillover can occur in nonreducible oxides when they possess substantial acid sites that aid the surface migration of active H. In the present review, we will discuss the possible mechanisms of H spillover in nonreducible oxides and the unique opportunities of using this phenomenon for the design of advanced hydroprocessing catalysts. [ABSTRACT FROM AUTHOR]

Published

2022

44. Boosting Hydrogen Evolution Reaction by Phase Engineering and Phosphorus Doping on Ru/P‐TiO2.

Author

Zhou, Shizheng, Jang, Haeseong, Qin, Qing, Hou, Liqiang, Kim, Min Gyu, Liu, Shangguo, Liu, Xien, and Cho, Jaephil

Subjects

HYDROGEN evolution reactions, DOPING agents (Chemistry), INTERSTITIAL hydrogen generation

Abstract

Synergistic optimization of the elementary steps of water dissociation and hydrogen desorption for the hydrogen evolution reaction (HER) in alkaline media is a challenge. Herein, the Ru cluster anchored on a trace P‐doped defective TiO2 substrate (Ru/P‐TiO2) was synthesized as an electrocatalyst for the HER; it exhibited a commercial Pt/C‐like geometric activity and an excellent mass activity of 9984.3 mA mgRu−1 at −0.05 V vs. RHE, which is 34.3 and 18.7 times higher than that of Pt/C and Ru/TiO2, respectively. Experimental and theoretical studies indicated that using a rutile‐TiO2‐crystal‐phase substrate enhanced the HER activity more than the anatase phase. Rich surface oxygen vacancies on rutile‐TiO2 facilitated the adsorption and dissociation of water, while the partial substitution of Ti4+ with P5+ enhanced H2 generation by facilitating hydrogen spillover from the Ru site to the surface P site, synergistically enhancing the HER activity. [ABSTRACT FROM AUTHOR]

Published

2022

45. Boosting Hydrogen Evolution Reaction by Phase Engineering and Phosphorus Doping on Ru/P‐TiO2.

Author

Zhou, Shizheng, Jang, Haeseong, Qin, Qing, Hou, Liqiang, Kim, Min Gyu, Liu, Shangguo, Liu, Xien, and Cho, Jaephil

Subjects

HYDROGEN evolution reactions, DOPING agents (Chemistry), INTERSTITIAL hydrogen generation

Abstract

Synergistic optimization of the elementary steps of water dissociation and hydrogen desorption for the hydrogen evolution reaction (HER) in alkaline media is a challenge. Herein, the Ru cluster anchored on a trace P‐doped defective TiO2 substrate (Ru/P‐TiO2) was synthesized as an electrocatalyst for the HER; it exhibited a commercial Pt/C‐like geometric activity and an excellent mass activity of 9984.3 mA mgRu−1 at −0.05 V vs. RHE, which is 34.3 and 18.7 times higher than that of Pt/C and Ru/TiO2, respectively. Experimental and theoretical studies indicated that using a rutile‐TiO2‐crystal‐phase substrate enhanced the HER activity more than the anatase phase. Rich surface oxygen vacancies on rutile‐TiO2 facilitated the adsorption and dissociation of water, while the partial substitution of Ti4+ with P5+ enhanced H2 generation by facilitating hydrogen spillover from the Ru site to the surface P site, synergistically enhancing the HER activity. [ABSTRACT FROM AUTHOR]

Published

2022

46. Fe2+/Fe3+ Cycling for Coupling Self‐Powered Hydrogen Evolution and Preparation of Electrode Catalysts.

Author

Chen, Chang, Fu, Zhengqian, Qi, Fenggang, Chen, Yafeng, Meng, Ge, Chang, Ziwei, Kong, Fantao, Zhu, Libo, Tian, Han, Huang, Haitao, Cui, Xiangzhi, and Shi, Jianlin

Subjects

HYDROGEN evolution reactions, FLOW batteries, HYDROGEN production, HYDROGEN, CATALYSTS, CATALYTIC activity, CATALYTIC converters for automobiles

Abstract

A novel Zn−Fe flow battery featuring an Fe3+ reduction reaction (Fe3+RR)‐coupled zinc oxidation, and an Fe2+ oxidation reaction (Fe2+OR)‐coupled hydrogen evolution reaction (HER) system as well, was established. This battery is capable of driving two Fe2+OR‐coupled HER systems in series based on the above Fe2+/Fe3+ cycling, for efficient self‐powered hydrogen evolution. Meanwhile, this Fe2+/Fe3+ cycling enables the preparation of a multifunctional catalyst, Pt‐3@SXNS (siloxene nanosheet), by the Fe2+OR‐promoted dispersion of Pt nanoparticles on SXNS; alternatively, this support could be obtained by Fe3+RR‐assisted exfoliation using Fe3+ from the anolyte of Fe2+OR‐coupled HER. The Pt‐3@SXNS catalyst exhibits excellent catalytic activities toward Fe3+RR in the Zn−Fe flow battery, HER, and Fe2+OR in the electrolyzer, which is attributed to the strong electronic interaction between Pt and Si. This work offers a new strategy for energy storage and low‐cost hydrogen production from acidic wastewater. [ABSTRACT FROM AUTHOR]

Published

2022

47. Fe2+/Fe3+ Cycling for Coupling Self‐Powered Hydrogen Evolution and Preparation of Electrode Catalysts.

Author

Chen, Chang, Fu, Zhengqian, Qi, Fenggang, Chen, Yafeng, Meng, Ge, Chang, Ziwei, Kong, Fantao, Zhu, Libo, Tian, Han, Huang, Haitao, Cui, Xiangzhi, and Shi, Jianlin

Subjects

HYDROGEN evolution reactions, FLOW batteries, HYDROGEN production, HYDROGEN, CATALYSTS, CATALYTIC converters for automobiles

Abstract

A novel Zn−Fe flow battery featuring an Fe3+ reduction reaction (Fe3+RR)‐coupled zinc oxidation, and an Fe2+ oxidation reaction (Fe2+OR)‐coupled hydrogen evolution reaction (HER) system as well, was established. This battery is capable of driving two Fe2+OR‐coupled HER systems in series based on the above Fe2+/Fe3+ cycling, for efficient self‐powered hydrogen evolution. Meanwhile, this Fe2+/Fe3+ cycling enables the preparation of a multifunctional catalyst, Pt‐3@SXNS (siloxene nanosheet), by the Fe2+OR‐promoted dispersion of Pt nanoparticles on SXNS; alternatively, this support could be obtained by Fe3+RR‐assisted exfoliation using Fe3+ from the anolyte of Fe2+OR‐coupled HER. The Pt‐3@SXNS catalyst exhibits excellent catalytic activities toward Fe3+RR in the Zn−Fe flow battery, HER, and Fe2+OR in the electrolyzer, which is attributed to the strong electronic interaction between Pt and Si. This work offers a new strategy for energy storage and low‐cost hydrogen production from acidic wastewater. [ABSTRACT FROM AUTHOR]

Published

2022

48. Incorporation of Hydrogen Isotopes into Biologically Active Compounds.

Author

Shevchenko, V. P., Nagaev, I. Yu., and Myasoedov, N. F.

Subjects

HYDROGEN isotopes, BIOACTIVE compounds, DEUTERIUM, TRITIUM, ISOTOPE exchange reactions, ORGANIC compounds, MOLECULAR weights

Abstract

The main approaches to the incorporation of tritium and deuterium labels into various classes of biologically active compounds (lipids, nucleotides, amino acids, peptides, low molecular weight bioregulators, etc.) are summarized. The preparation of organic compounds labeled with hydrogen isotopes using various physicochemical methods is described. The effect of reaction conditions on the yield and content of hydrogen isotopes in labeled preparations is considered. Much attention is paid to the incorporation of deuterium and tritium through isotope exchange. Possible mechanisms for the incorporation of hydrogen isotopes and the distribution of the label in organic compounds associated with these processes are demonstrated. It was shown that irradiation of preparations, the use of intermediates, and other innovations can significantly improve the parameters of the desired labeled biologically active compounds. [ABSTRACT FROM AUTHOR]

Published

2022

49. Hydrogen spillover on cerium-based catalysts.

Author

Vikanova, K. V., Redina, E. A., and Kustov, L. M.

Subjects

HYDROGEN, CATALYSTS, CATALYTIC hydrogenation

Abstract

Data on hydrogen spillover (HS) in catalytic processes are systematized. Different opinions on the mechanism and participation of HS in various reactions are presented. Hydrogen spillover on CeO2-based systems and physicochemical methods of investigation of the phenomenon are considered. Tentative mechanisms of HS are described and the role of HS in catalytic hydrogenation reactions is studied. [ABSTRACT FROM AUTHOR]

Published

2022

50. Ultrahigh Pt‐Mass‐Activity Hydrogen Evolution Catalyst Electrodeposited from Bulk Pt.

Author

Liu, Luan, Wang, Yan, Zhao, Yongzhi, Wang, Yong, Zhang, Zili, Wu, Tong, Qin, Wanjun, Liu, Sijia, Jia, Baorui, Wu, Haoyang, Zhang, Deyin, Qu, Xuanhui, Chhowalla, Manish, and Qin, Mingli

Subjects

HYDROGEN evolution reactions, FOAM, HYDROGEN, ELECTROCHEMICAL experiments, CATALYSTS, ELECTROCATALYSTS

Abstract

Maximizing the Pt utilization is important for the widescale implementation of Pt‐based hydrogen evolution reaction (HER) electrocatalysts, owing to the scarcity of Pt. Here, three‐component heterostructured HER catalysts with ultrahigh Pt mass activity in which hollow PtCu alloy nanospheres are supported on an array of WO3 on Cu foam, are reported. It has been pointed out that the use of Pt counter electrode in a three‐electrode configuration in evaluating catalysts' HER performances in acidic media carries the risk of contaminating the working electrode in previous reports. Here, the authors rationally utilize this "contaminating" to "activate" low‐HER‐activity materials, maximizing the Pt utilization. As a result, ultrahigh Pt mass activity is achieved, that is 1.35 and 10.86 A mg−1Pt at overpotentials of 20 and 100 mV, respectively, 27 and 13 times higher than those of commercial Pt/C catalysts, outperforming some state‐of‐the‐art Pt‐single‐atom catalysts. The hollow sphere structure and PtCu alloying increase the number and reactivity of active sites. Density function calculations and electrochemical experiments reveal that the synergy between WO3 and Pt is also responsible for the high HER activity where the hydrogen spillover effect triggers the Volmer–Heyrovsky mechanism and promotes the rapid removal of H* from Pt to re‐expose the active sites. [ABSTRACT FROM AUTHOR]

Published

2022