Your search keyword '"Wang, Maoyu"' showing total 9 results

1. Active Sites of Cobalt Phthalocyanine in Electrocatalytic CO2 Reduction to Methanol.

Author

Rooney, Conor L., Lyons, Mason, Wu, Yueshen, Hu, Gongfang, Wang, Maoyu, Choi, Chungseok, Gao, Yuanzuo, Chang, Chun‐Wai, Brudvig, Gary W., Feng, Zhenxing, and Wang, Hailiang

Subjects

X-ray absorption, COBALT, X-ray spectroscopy, CHARGE exchange, METHANOL production, COORDINATION compounds

Abstract

Many metal coordination compounds catalyze CO2 electroreduction to CO, but cobalt phthalocyanine hybridized with conductive carbon such as carbon nanotubes is currently the only one that can generate methanol. The underlying structure–reactivity correlation and reaction mechanism desperately demand elucidation. Here we report the first in situ X‐ray absorption spectroscopy characterization, combined with ex situ spectroscopic and electrocatalytic measurements, to study CoPc‐catalyzed CO2 reduction to methanol. Molecular dispersion of CoPc on CNT surfaces, as evidenced by the observed electronic interaction between the two, is crucial to fast electron transfer to the active sites and multi‐electron CO2 reduction. CO, the key intermediate in the CO2‐to‐methanol pathway, is found to be labile on the active site, which necessitates a high local concentration in the microenvironment to compete with CO2 for active sites and promote methanol production. A comparison of the electrocatalytic performance of structurally related porphyrins indicates that the bridging aza‐N atoms of the Pc macrocycle are critical components of the CoPc active site that produces methanol. In situ X‐ray absorption spectroscopy identifies the active site as Co(I) and supports an increasingly non‐centrosymmetric Co coordination environment at negative applied potential, likely due to the formation of a Co−CO adduct during the catalysis. [ABSTRACT FROM AUTHOR]

Published

2024

2. Cascade electrocatalysis via AgCu single-atom alloy and Ag nanoparticles in CO2 electroreduction toward multicarbon products.

Author

Du, Cheng, Mills, Joel P., Yohannes, Asfaw G., Wei, Wei, Wang, Lei, Lu, Siyan, Lian, Jian-Xiang, Wang, Maoyu, Guo, Tao, Wang, Xiyang, Zhou, Hua, Sun, Cheng-Jun, Wen, John Z., Kendall, Brian, Couillard, Martin, Guo, Hongsheng, Tan, ZhongChao, Siahrostami, Samira, and Wu, Yimin A.

Subjects

ELECTROCATALYSIS, ELECTROLYTIC reduction, COPPER, CARBON cycle, COUPLING reactions (Chemistry), NANOPARTICLES

Abstract

Electrocatalytic CO2 reduction into value-added multicarbon products offers a means to close the anthropogenic carbon cycle using renewable electricity. However, the unsatisfactory catalytic selectivity for multicarbon products severely hinders the practical application of this technology. In this paper, we report a cascade AgCu single-atom and nanoparticle electrocatalyst, in which Ag nanoparticles produce CO and AgCu single-atom alloys promote C-C coupling kinetics. As a result, a Faradaic efficiency (FE) of 94 ± 4% toward multicarbon products is achieved with the as-prepared AgCu single-atom and nanoparticle catalyst under ~720 mA cm−2 working current density at −0.65 V in a flow cell with alkaline electrolyte. Density functional theory calculations further demonstrate that the high multicarbon product selectivity results from cooperation between AgCu single-atom alloys and Ag nanoparticles, wherein the Ag single-atom doping of Cu nanoparticles increases the adsorption energy of *CO on Cu sites due to the asymmetric bonding of the Cu atom to the adjacent Ag atom with a compressive strain. Electrocatalytic CO2 reduction into multicarbon products offers a means to close the anthropogenic carbon cycle using renewable electricity. Here, the authors report a cascade AgCu single-atom and nanoparticle electrocatalyst with favorable properties to improve the selectivity of multicarbon products. [ABSTRACT FROM AUTHOR]

Published

2023

3. Atomically Dispersed Dual‐Metal Site Catalysts for Enhanced CO2 Reduction: Mechanistic Insight into Active Site Structures.

Author

Li, Yi, Shan, Weitao, Zachman, Michael J., Wang, Maoyu, Hwang, Sooyeon, Tabassum, Hassina, Yang, Juan, Yang, Xiaoxuan, Karakalos, Stavros, Feng, Zhenxing, Wang, Guofeng, and Wu, Gang

Subjects

CATALYSTS, CATALYTIC activity, ELECTROLYTIC reduction, ATOMS, ADSORPTION (Chemistry)

Abstract

Carbon‐supported nitrogen‐coordinated single‐metal site catalysts (i.e., M−N−C, M: Fe, Co, or Ni) are active for the electrochemical CO2 reduction reaction (CO2RR) to CO. Further improving their intrinsic activity and selectivity by tuning their N−M bond structures and coordination is limited. Herein, we expand the coordination environments of M−N−C catalysts by designing dual‐metal active sites. The Ni‐Fe catalyst exhibited the most efficient CO2RR activity and promising stability compared to other combinations. Advanced structural characterization and theoretical prediction suggest that the most active N‐coordinated dual‐metal site configurations are 2N‐bridged (Fe‐Ni)N6, in which FeN4 and NiN4 moieties are shared with two N atoms. Two metals (i.e., Fe and Ni) in the dual‐metal site likely generate a synergy to enable more optimal *COOH adsorption and *CO desorption than single‐metal sites (FeN4 or NiN4) with improved intrinsic catalytic activity and selectivity. [ABSTRACT FROM AUTHOR]

Published

2022

4. Binary Atomically Dispersed Metal‐Site Catalysts with Core−Shell Nanostructures for O2 and CO2 Reduction Reactions.

Author

Yang, Xiaoxuan, Wang, Maoyu, Zachman, Michael J., Zhou, Hua, He, Yanghua, Liu, Shengwen, Zang, Hong-Ying, Feng, Zhenxing, and Wu, Gang

Subjects

*NANOSTRUCTURED materials, *CARBON dioxide reduction, *POLYMERIZATION, *CATALYTIC activity, *CHARGE transfer, *FUEL cells

Abstract

Engineering atomically dispersed metal site catalysts with controlled local coordination environments and 3D nanostructures effectively improves the catalytic performance for the oxygen reduction reaction (ORR) and the carbon dioxide reduction reaction (CO2RR), which are critical for clean energy conversion and chemical production. Herein, an innovative approach for preparing core−shell nanostructured catalysts with different single‐metal sites in the core and the shell, respectively, is developed. In particular, as the shell precursors, covalent organic polymers with a thin layered structure that is polymerized in situ and coated on a metal‐doped ZIF‐derived carbon core are used, followed by a controlled thermal activation. The selective combination and construction of different metal sites increase active site density in the surface layers, promote structural robustness, facilitate mass/charge transfer, and yield a possible synergy of active sites in the core and the shell. The p‐FeNC(shell)@CoNC(core), consisting of a polymerized FeTPPCl‐derived carbon layer (p‐FeNC) on a Co‐doped ZIF‐derived carbon (CoNC), exhibits remarkable ORR activity and stability in acidic media along with encouraging durability in H2–air fuel cells. Likewise, a p‐FeNC(shell)@NiNC(core) catalyst demonstrates outstanding CO2RR activity and stability. Hence, integrating two appropriate single‐metal sites in core and shell precursors, respectively, can modulate morphological and catalytic properties for a possible synergy toward different electrocatalysis processes. [ABSTRACT FROM AUTHOR]

Published

2021

5. Porous FeCo Glassy Alloy as Bifunctional Support for High‐Performance Zn‐Air Battery.

Author

Pan, Fuping, Li, Zhao, Yang, Zhenzhong, Ma, Qing, Wang, Maoyu, Wang, Han, Olszta, Matthew, Wang, Guanzhi, Feng, Zhenxing, Du, Yingge, and Yang, Yang

Subjects

METALLIC glasses, OXYGEN reduction, POWER density, ELECTRIC batteries, ELECTROCATALYSTS

Abstract

The Zn‐air battery (ZAB) is attracting increasing attention due to its high safety and preeminent performance. However, the practical application of ZAB relies heavily on developing durable support materials to replace conventional carbon supports which have unrecoverable corrosion issues, severely jeopardizing ZAB performance. Herein, a novel porous FeCo glassy alloy is developed as a bifunctional catalytic support for ZAB. The conducting skeleton of the porous glassy alloy is used to stabilize oxygen reduction cocatalysts, and more importantly, the FeCo serves as the primary phase for oxygen evolution. To demonstrate the concept of catalytic glassy alloy support, ultrasmall Pd nanoparticles are anchored, as oxygen reduction active sites, on the porous FeCo (noted as Pd/FeCo) for ZAB. The Pd/FeCo exhibits a significantly improved electrocatalytic activity for oxygen reduction (a half‐wave potential of 0.85 V) and oxygen evolution (a potential of 1.55 V to reach 10 mA cm−2) in the alkaline media. When used in the ZAB, the Pd/FeCo delivers an output power density of 117 mW cm−2 and outstanding cycling stability for over 200 h (400 cycles), surpassing the conventional carbon‐supported Pt/C+IrO2 catalysts. Such an integrated design that combines highly active components with a porous architecture provides a new strategy to develop novel nanostructured electrocatalysts. [ABSTRACT FROM AUTHOR]

Published

2021

6. Partial‐Single‐Atom, Partial‐Nanoparticle Composites Enhance Water Dissociation for Hydrogen Evolution.

Author

Hu, Chun, Song, Erhong, Wang, Maoyu, Chen, Wei, Huang, Fuqiang, Feng, Zhenxing, Liu, Jianjun, and Wang, Jiacheng

Subjects

HYDROGEN evolution reactions, METHANE hydrates, HYDROGEN, WATER

Abstract

The development of an efficient electrocatalyst toward the hydrogen evolution reaction (HER) is of significant importance in transforming renewable electricity to pure and clean hydrogen by water splitting. However, the construction of an active electrocatalyst with multiple sites that can promote the dissociation of water molecules still remains a great challenge. Herein, a partial‐single‐atom, partial‐nanoparticle composite consisting of nanosized ruthenium (Ru) nanoparticles (NPs) and individual Ru atoms as an energy‐efficient HER catalyst in alkaline medium is reported. The formation of this unique composite mainly results from the dispersion of Ru NPs to small‐size NPs and single atoms (SAs) on the Fe/N codoped carbon (Fe–N–C) substrate due to the thermodynamic stability. The optimal catalyst exhibits an outstanding HER activity with an ultralow overpotential (9 mV) at 10 mA cm−2 (η10), a high turnover frequency (8.9 H2 s−1 at 50 mV overpotential), and nearly 100% Faraday efficiency, outperforming the state‐of‐the‐art commercial Pt/C and other reported HER electrocatalysts in alkaline condition. Both experimental and theoretical calculations reveal that the coexistence of Ru NPs and SAs can improve the hydride coupling and water dissociation kinetics, thus synergistically enhancing alkaline hydrogen evolution performance. [ABSTRACT FROM AUTHOR]

Published

2021

7. Chemical Vapor Deposition for Atomically Dispersed and Nitrogen Coordinated Single Metal Site Catalysts.

Author

Liu, Shengwen, Wang, Maoyu, Yang, Xiaoxuan, Shi, Qiurong, Qiao, Zhi, Lucero, Marcos, Ma, Qing, More, Karren L., Cullen, David A., Feng, Zhenxing, and Wu, Gang

Subjects

*CHEMICAL vapor deposition, *METAL catalysts, *CATALYSTS, *POROUS metals, *FUEL cells, *NITROGEN

Abstract

Atomically dispersed and nitrogen coordinated single metal sites (M‐N‐C, M=Fe, Co, Ni, Mn) are the popular platinum group‐metal (PGM)‐free catalysts for many electrochemical reactions. Traditional wet‐chemistry catalyst synthesis often requires complex procedures with unsatisfied reproducibility and scalability. Here, we report a facile chemical vapor deposition (CVD) strategy to synthesize the promising M‐N‐C catalysts. The deposition of gaseous 2‐methylimidazole onto M‐doped ZnO substrates, followed by an in situ thermal activation, effectively generated single metal sites well dispersed into porous carbon. In particular, an optimal CVD‐derived Fe‐N‐C catalyst exclusively contains atomically dispersed FeN4 sites with increased Fe loading relative to other catalysts from wet‐chemistry synthesis. The catalyst exhibited outstanding oxygen‐reduction activity in acidic electrolytes, which was further studied in proton‐exchange membrane fuel cells with encouraging performance. [ABSTRACT FROM AUTHOR]

Published

2020

8. Atomically Dispersed Single Ni Site Catalysts for Nitrogen Reduction toward Electrochemical Ammonia Synthesis Using N2 and H2O.

Author

Mukherjee, Shreya, Yang, Xiaoxuan, Shan, Weitao, Samarakoon, Widitha, Karakalos, Stavros, Cullen, David A., More, Karren, Wang, Maoyu, Feng, Zhenxing, Wang, Guofeng, and Wu, Gang

Subjects

ELECTROLYTIC reduction, AMMONIA, BURNUP (Nuclear chemistry), STANDARD hydrogen electrode, ELECTRON spectroscopy, CATALYSTS, NITROGEN

Abstract

Ammonia (NH3) electrosynthesis gains significant attention as NH3 is essentially important for fertilizer production and fuel utilization. However, electrochemical nitrogen reduction reaction (NRR) remains a great challenge because of low activity and poor selectivity. Herein, a new class of atomically dispersed Ni site electrocatalyst is reported, which exhibits the optimal NH3 yield of 115 µg cm−2 h−1 at –0.8 V versus reversible hydrogen electrode (RHE) under neutral conditions. High faradic efficiency of 21 ± 1.9% is achieved at ‐0.2 V versus RHE under alkaline conditions, although the ammonia yield is lower. The Ni sites are stabilized with nitrogen, which is verified by advanced X‐ray absorption spectroscopy and electron microscopy. Density functional theory calculations provide insightful understanding on the possible structure of active sites, relevant reaction pathways, and confirm that the Ni‐N3 sites are responsible for the experimentally observed activity and selectivity. Extensive controls strongly suggest that the atomically dispersed NiN3 site‐rich catalyst provides more intrinsically active sites than those in N‐doped carbon, instead of possible environmental contamination. This work further indicates that single‐metal site catalysts with optimal nitrogen coordination is very promising for NRR and indeed improves the scaling relationship of transition metals. [ABSTRACT FROM AUTHOR]

Published

2020

9. Single-Iron Site Catalysts with Self-Assembled Dual-size Architecture and Hierarchical Porosity for Proton-Exchange Membrane Fuel Cells.

Author

Zhao, Xiaolin, Yang, Xiaoxuan, Wang, Maoyu, Hwang, Sooyeon, Karakalos, Stavros, Chen, Mengjie, Qiao, Zhi, Wang, Lei, Liu, Bin, Ma, Qing, Cullen, David A., Su, Dong, Yang, Haipeng, Zang, Hong-Ying, Feng, Zhenxing, and Wu, Gang

Subjects

*FUEL cells, *PLATINUM group, *CELL membranes, *OXYGEN reduction, *CATALYSTS, *AGGLOMERATION (Materials), *COLLOIDAL crystals, *ELECTROCATALYSTS

Abstract

• We report a self-assembled strategy to synthesize 3D superstructure single Fe site electrocatalysts. • Unlike homogeneous particle morphologies, we developed a catalyst with small particles uniformly dispersed onto large particles. • The unique dual sized particle morphology can mitigate the particle aggregates during the synthesis and reaction. • The catalyst with optimal size combination represents one of the best ORR activity in both acidic electrolyte and MEAs. Atomically dispersed and nitrogen coordinated single iron site (i.e., FeN 4) catalysts (Fe-N-C) are the most promising platinum group metal (PGM)-free cathode for the oxygen reduction reaction (ORR) in proton-exchange membrane fuel cells (PEMFCs). However, current Fe-N-C catalysts are limited by the inferior exposure of active FeN 4 sites due to the inevitable agglomeration of particles in cathodes. Herein, we report a self-assembled strategy to synthesize the atomically dispersed FeN 4 site catalysts with a hierarchically porous matrix derived from dual-size Fe-doped ZIF-8 crystal precursors by using large particles to support small particles. The tailored structure is effective in mitigating the particle migration, agglomeration, and spatial overlap, thereby exposing increased accessible active sites and facilitating mass transport. The best performing catalyst composed of 100 nm "nucleated seed" assembled by 30 nm "satellite" demonstrates exceptional ORR activity in acidic electrolyte and membrane electrode assembly. This work provides new concepts for designing hierarchically porous catalysts with single metal atom dispersion via self-assembly of ZIF-8 crystal precursors with tunable particle sizes and nanostructures. [ABSTRACT FROM AUTHOR]

Published

2020