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4. Full‐Spectrum Light‐Harvesting Solar Thermal Electrocatalyst Boosts Oxygen Evolution.

Author

Xu, Mingxia, Bing, Qiming, Tu, Yunchuan, Zhang, Yunlong, Zhang, Mo, Cai, Yafeng, Li, Jinlei, Meng, Xianguang, Zhu, Jia, Yu, Liang, and Deng, Dehui

Subjects
SOLAR thermal energy, OXYGEN evolution reactions, SOLAR energy, NANOPARTICLES, ELECTRONIC structure, SOLAR spectra
Abstract

Enabling high‐efficiency solar thermal conversion (STC) at catalytic active site is critical but challenging for harnessing solar energy to boost catalytic reactions. Herein, we report the direct integration of full‐spectrum STC and high electrocatalytic oxygen evolution activity by fabricating a hierarchical nanocage architecture composed of graphene‐encapsulated CoNi nanoparticle. This catalyst exhibits a near‐complete 98 % absorptivity of solar spectrum and a high STC efficiency of 97 %, which is superior than previous solar thermal catalytic materials. It delivers a remarkable potential decrease of over 240 mV at various current densities for electrocatalytic oxygen evolution under solar illumination, which is practically unachievable via traditionally heating the system. The high‐efficiency STC is enabled by a synergy between the regulated electronic structure of graphene via CoNi‐carbon interaction and the multiple absorption of lights by the light‐trapping nanocage. Theoretical calculations suggest that high temperature‐induced vibrational free energy gain promotes the potential‐limiting *O to *OOH step, which decreases the overpotential for oxygen evolution. [ABSTRACT FROM AUTHOR]

Published
2024
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8. Electrocatalytic synthesis of C–N coupling compounds from CO2 and nitrogenous species

Author

Zhang, Zheng, primary, Li, Danyang, additional, Tu, Yunchuan, additional, Deng, Jiao, additional, Bi, Huiting, additional, Yao, Yongchao, additional, Wang, Yan, additional, Li, Tingshuai, additional, Luo, Yongsong, additional, Sun, Shengjun, additional, Zheng, Dongdong, additional, Carabineiro, Sónia A. C., additional, Chen, Zhou, additional, Zhu, Junjiang, additional, and Sun, Xuping, additional

Published
2024
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13. Electrocatalytic synthesis of C–N coupling compounds from CO2 and nitrogenous species.

Author

Zhang, Zheng, Li, Danyang, Tu, Yunchuan, Deng, Jiao, Bi, Huiting, Yao, Yongchao, Wang, Yan, Li, Tingshuai, Luo, Yongsong, Sun, Shengjun, Zheng, Dongdong, Carabineiro, Sónia A. C., Chen, Zhou, Zhu, Junjiang, and Sun, Xuping

Subjects
COUPLING reactions (Chemistry), CARBON offsetting, OXIDATION of water, POLLUTION, SPECIES
Abstract

The electrocatalytic synthesis of C–N coupling compounds from CO2 and nitrogenous species not only offers an effective avenue to achieve carbon neutrality and reduce environmental pollution, but also establishes a route to synthesize valuable chemicals, such as urea, amide, and amine. This innovative approach expands the application range and product categories beyond simple carbonaceous species in electrocatalytic CO2 reduction, which is becoming a rapidly advancing field. This review summarizes the research progress in electrocatalytic urea synthesis, using N2, NO2−, and NO3− as nitrogenous species, and explores emerging trends in the electrosynthesis of amide and amine from CO2 and nitrogen species. Additionally, the future opportunities in this field are highlighted, including electrosynthesis of amino acids and other compounds containing C–N bonds, anodic C–N coupling reactions beyond water oxidation, and the catalytic mechanism of corresponding reactions. This critical review also captures the insights aimed at accelerating the development of electrochemical C–N coupling reactions, confirming the superiority of this electrochemical method over the traditional techniques. [ABSTRACT FROM AUTHOR]

Published
2024
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17. Back Cover: Full‐Spectrum Light‐Harvesting Solar Thermal Electrocatalyst Boosts Oxygen Evolution (Angew. Chem. Int. Ed. 52/2024).

Author

Xu, Mingxia, Bing, Qiming, Tu, Yunchuan, Zhang, Yunlong, Zhang, Mo, Cai, Yafeng, Li, Jinlei, Meng, Xianguang, Zhu, Jia, Yu, Liang, and Deng, Dehui

Subjects
SOLAR energy, CATALYSTS, OXYGEN
Abstract

The article in the journal "Angewandte Chemie International Edition" discusses the development of a solar thermal electrocatalyst that enhances oxygen evolution through full-spectrum light-harvesting. Researchers, including Dehui Deng and Liang Yu, have created a hierarchical nanocage architecture that achieves high solar absorptivity and lowers the potential for the oxygen evolution reaction. This innovative approach could significantly improve the efficiency of catalytic reactions powered by solar energy. [Extracted from the article]

Published
2024
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18. Rücktitelbild: Full‐Spectrum Light‐Harvesting Solar Thermal Electrocatalyst Boosts Oxygen Evolution (Angew. Chem. 52/2024).

Author

Xu, Mingxia, Bing, Qiming, Tu, Yunchuan, Zhang, Yunlong, Zhang, Mo, Cai, Yafeng, Li, Jinlei, Meng, Xianguang, Zhu, Jia, Yu, Liang, and Deng, Dehui

Subjects
SOLAR energy, CATALYSTS, OXYGEN
Abstract

The article in Angewandte Chemie discusses the development of a highly efficient solar thermal conversion (STC) catalyst for boosting catalytic reactions using solar energy. Researchers, including Dehui Deng and Liang Yu, integrated full-spectrum STC and electrocatalytic oxygen evolution activity on a "Chainmail" catalyst with a hierarchical nanocage architecture. This innovation achieved a 98% solar absorptivity and significantly decreased the potential for the oxygen evolution reaction by over 240 mV. [Extracted from the article]

Published
2024
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21. Probing the active sites of 2D nanosheets with Fe-N-C carbon shell encapsulated FexC/Fe species for boosting sodium-ion storage performances

Author

Xia, Huicong, primary, Yuan, Pengfei, additional, Zan, Lingxing, additional, Qu, Gan, additional, Tu, Yunchuan, additional, Zhu, Kaixin, additional, Wei, Yifan, additional, Wei, Zeyu, additional, Zheng, Fangying, additional, Zhang, Mo, additional, Hu, Yongfeng, additional, Deng, Dehui, additional, and Zhang, Jianan, additional

Published
2021
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24. Probing the active sites of 2D nanosheets with Fe-N-C carbon shell encapsulated FexC/Fe species for boosting sodium-ion storage performances.

Author

Xia, Huicong, Yuan, Pengfei, Zan, Lingxing, Qu, Gan, Tu, Yunchuan, Zhu, Kaixin, Wei, Yifan, Wei, Zeyu, Zheng, Fangying, Zhang, Mo, Hu, Yongfeng, Deng, Dehui, and Zhang, Jianan

Abstract

Developing stable but high active metal-nitrogen-carbon (M-N-C)-based hard carbon anode is a promising way to be the alternatives to graphene and blank hard carbon for sodium-ion batteries (SIBs), requiring the precise tailoring of the electronic structure for optimizing the Na+ intercalation behavior, yet is greatly challenging. Herein, Fe-N-C graphitic layer-encapsulating Fe3C species within hard carbon nanosheets (Fe-N-C/Fe3C@HCNs) are rationally engineered by pyrolysis of self-assembled polymer. Impressively, the Fe-N-C/Fe3C@HCNs exhibit outstanding rate capacity (242 mAh·g−1 at 2,000 mA·g−1), which is 2.1 and 4.2 times higher than that of Fe-N-C and N-doped carbon (N-C), respectively, and prolonged cycling stability (176 mAh·g−1 at 2,000 mA·g−1 after 2,000 cycles). Theoretical calculations unveil that the Fe3C species enhance the electronic transfer from Na to Fe-N-C, resulting in the charge redistribution between the interfaces of Fe3C and Fe-N-C. Thus, the optimized adsorption behavior towards Na+ reduces the thermodynamic energy barriers. The synergistic effect of Fe3C and Fe-N-C species maintains the structural integrity of electrode materials during the sodiation/desodiation process. The in-depth insight into the advanced Na+ storage mechanisms of Fe3C@Fe-N-C offers precise guidance for the rational establishment of confinement heterostructures in SIBs. [ABSTRACT FROM AUTHOR]

Published
2022
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33. 3D MoS2foam integrated with carbon paper as binder-free anode for high performance sodium-ion batteries

Author

Zheng, Fangying, Wei, Zeyu, Xia, Huicong, Tu, Yunchuan, Meng, Xiangyu, Zhu, Kaixin, Zhao, Jiao, Zhu, Yimin, Zhang, Jianan, Yang, Yan, and Deng, Dehui

Abstract

3D MoS2foam integrated with carbon paper (3D F-MoS2/CP) was synthesized in large-scale (up to 20 × 20 cm2) and used as binder-free electrode directly. It showed a superior initial discharge capacity (1080 mA h g−1at 2000 mA g−1), rate performance and cycling stability, and can be cycled at 2000 mA g−1for 1000 cycles with an extremely low decay rate (0.033% per cycle) in sodium-ion batteries.

Published
2022
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35. Distance Synergy of MoS2‐Confined Rhodium Atoms for Highly Efficient Hydrogen Evolution.

Author

Meng, Xiangyu, Ma, Chao, Jiang, Luozhen, Si, Rui, Meng, Xianguang, Tu, Yunchuan, Yu, Liang, Bao, Xinhe, and Deng, Dehui

Subjects
HYDROGEN evolution reactions, RHODIUM, ATOMS, DISTANCES, ELECTRONIC structure, HYDROGEN
Abstract

Perturbing the electronic structure of the MoS2 basal plane by confining heteroatoms offers the opportunity to trigger in‐plane activity for the hydrogen evolution reaction (HER). The key challenge consists of inducing the optimum HER activity by controlling the type and distribution of confined atoms. A distance synergy of MoS2‐confined single‐atom rhodium is presented, leading to an ultra‐high HER activity at the in‐plane S sites adjacent to the rhodium. By optimizing the distance between the confined Rh atoms, an ultra‐low overpotential of 67 mV is achieved at a current density of 10 mA cm−2 in acidic solution. Experiments and first‐principles calculations demonstrate a unique distance synergy between the confined rhodium atoms in tuning the reactivity of neighboring in‐plane S atoms, which presents a volcanic trend with the inter‐rhodium distance. This study provides a new strategy to tailor the activity of MoS2 surface via modulating the distance between confined single atoms. [ABSTRACT FROM AUTHOR]

Published
2020
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37. Multiscale carbon foam confining single iron atoms for efficient electrocatalytic CO2 reduction to CO.

Author

Zhang, Zheng, Ma, Chao, Tu, Yunchuan, Si, Rui, Wei, Jie, Zhang, Shuhong, Wang, Zhen, Li, Jian-Feng, Wang, Ye, and Deng, Dehui

Abstract

Electrocatalytic CO2 reduction to CO is a sustainable process for energy conversion. However, this process is still hindered by the diffusion-limited mass transfer, low electrical conductivity and catalytic activity. Therefore, new strategies for catalyst design should be adopted to solve these problems and improve the electrocatalytic performance for CO production. Herein, we report a multiscale carbon foam confining single iron atoms prepared with the assistant of SiO2 template. The pore-enriched environment at the macro-scale facilitates the diffusion of reactants and products. The graphene nanosheets at the nano-scale promote the charge transfer during the reaction. The single iron atoms confined in carbon matrix at the atomic-scale provide the active sites for electrocatalytic CO2 reduction to CO. The optimized catalyst achieves a CO Faradaic efficiency of 94.9% at a moderate potential of −0.5 V vs. RHE. Furthermore, the performance can be maintained over 60 hours due to the stable single iron atoms coordinated with four nitrogen atoms in the carbon matrix. This work provides a promising strategy to improve both the activity and stability of single atom catalysts for electrocatalytic CO2 reduction to CO. [ABSTRACT FROM AUTHOR]

Published
2019
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40. Balanced Adsorption Toward Highly Selective Electrochemical Reduction of CO 2 to Formate.

Author

Su D, Zhang J, Liu J, Lv S, Xie Z, Tu Y, Hu X, Li C, Liu B, and Wei Z

Abstract

Tin-based materials have been designed as potential catalysts for the electrochemical conversion of CO 2 into a single product. However, such tin-based materials still face the challenges of unsatisfactory selectivity, because the rate-determining step is situated within the slow desorption step. In this work, a variety of tin-based materials are synthesized using the electrospinning technique in an effort to control the adsorption strength during electrochemical reduction, therefore improving the selectivity of CO 2 reduction toward formate. The optimized SnS material exhibits moderate adsorption strength to *OCHO and *HCOOH, and the appropriate atomic distance of Sn-Sn maintained the balanced adsorption posture of both intermediate. Therefore, the rate-determining step can be shifted from the slow desorption of the *HCOOH step (Sn) to the first hydrogenation of the *OCHO species step (SnS). Due to this shift, the SnS/C electrode demonstrated excellent selectivity, with a Faradaic efficiency of 96% for the production of formate. A maximum current density of -12.5 mA cm -2 for formate is also achieved for a period of 33 h., (© 2024 Wiley‐VCH GmbH.)

Published
2025
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