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2. Improving Pd–N–C fuel cell electrocatalysts through fluorination-driven rearrangements of local coordination environment

Author

Meng Gu, Qi Wang, Boyang Li, Maoyu Wang, Guanzhi Wang, Yuanmin Zhu, Qing Ma, Yang Yang, Zhenxing Feng, Mahmoud Omer, Jinfa Chang, Nina Orlovskaya, Guofeng Wang, Wei Zhang, and Hua Zhou

Subjects
inorganic chemicals, Ethanol, Renewable Energy, Sustainability and the Environment, Heteroatom, Rational design, Energy Engineering and Power Technology, chemistry.chemical_element, Direct-ethanol fuel cell, Combinatorial chemistry, Electronic, Optical and Magnetic Materials, Catalysis, Metal, chemistry.chemical_compound, Fuel Technology, chemistry, Phase (matter), visual_art, visual_art.visual_art_medium, Carbon
Abstract

The local coordination environment around catalytically active sites plays a vital role in tuning the activity of electrocatalysts made of carbon-supported metal nanoparticles. However, the rational design of electrocatalysts with improved performance by controlling this environment is hampered by synthetic limitations and insufficient mechanistic understanding of how the catalytic phase forms. Here we show that introducing F atoms into Pd/N–C catalysts modifies the environment around the Pd and improves both activity and durability for the ethanol oxidation reaction and the oxygen reduction reaction. Our data suggest that F atom introduction creates a more N-rich Pd surface, which is favourable for catalysis. Durability is enhanced by inhibition of Pd migration and decreased carbon corrosion. A direct ethanol fuel cell that uses the Pd/N–C catalyst with F atoms introduced for both the ethanol oxidation reaction and oxygen reduction reaction achieves a maximum power density of 0.57 W cm−2 and more than 5,900 hours of operation. Pd/C catalysts containing other heteroatoms (P, S, B) can also be improved through the addition of F atoms. Metal- and N-coordinated carbon materials are promising electrocatalysts, but improved activity and stability are desirable for fuel cell applications. Chang et al. address this by introducing F atoms into Pd/N–C catalysts, modifying the environment around the Pd and enhancing performance for ethanol oxidation and oxygen reduction.

Published
2021

3. Single Iridium Atom Doped Ni2P Catalyst for Optimal Oxygen Evolution

Author

Maoyu Wang, Joseph S. Francisco, Shaobo Han, Xiang Huang, Qi Wang, Meng Gu, Hua Zhou, Chao Cai, Zhenxing Feng, Zhe Zhang, Lei Li, Hu Xu, Zhi Liang Zhao, Menghao Li, and Jun Li

Subjects
Doping, Oxygen evolution, chemistry.chemical_element, General Chemistry, Overpotential, Biochemistry, Catalysis, Colloid and Surface Chemistry, Adsorption, Chemical engineering, chemistry, Desorption, Iridium, Current density
Abstract

Single-atom catalysts (SACs) with 100% active sites have excellent prospects for application in the oxygen evolution reaction (OER). However, further enhancement of the catalytic activity for OER is quite challenging, particularly for the development of stable SACs with overpotentials

Published
2021

4. Iron-Imprinted Single-Atomic Site Catalyst-Based Nanoprobe for Detection of Hydrogen Peroxide in Living Cells

Author

Shichao Ding, Yuehe Lin, Xiaoqing Pan, Zhenxing Feng, Maoyu Wang, Zhaoyuan Lyu, Chengzhou Zhu, Dan Du, and Hangyu Tian

Subjects
In situ, Technology, Materials science, Peroxidase-like activities, biology, Biosensing, Nanoprobe, Single-atomic site catalysts, Active site, Nanotechnology, Living cell, Article, Surfaces, Coatings and Films, Electronic, Optical and Magnetic Materials, Catalysis, chemistry.chemical_compound, chemistry, Biocatalysis, biology.protein, Electrical and Electronic Engineering, Hydrogen peroxide, Biosensor
Abstract

Highlights A facile ion-imprinting method (IIM) is used to synthesize the isolated Fe-N-C single-atomic site catalyst (IIM-Fe-SASC), which mimics the natural enzyme-like active site and shows excellent peroxidase-like activity.The ion-imprinting process can precisely control ion at the atomic level and form numerous well-defined single-atomic Fe-N-C sites.The IIM-Fe-SASC has been successfully used as the nanoprobe for in situ H2O2 detection generated from MDA-MB-231 cells. Supplementary Information The online version contains supplementary material available at 10.1007/s40820-021-00661-z., Fe-based single-atomic site catalysts (SASCs), with the natural metalloproteases-like active site structure, have attracted widespread attention in biocatalysis and biosensing. Precisely, controlling the isolated single-atom Fe-N-C active site structure is crucial to improve the SASCs’ performance. In this work, we use a facile ion-imprinting method (IIM) to synthesize isolated Fe-N-C single-atomic site catalysts (IIM-Fe-SASC). With this method, the ion-imprinting process can precisely control ion at the atomic level and form numerous well-defined single-atomic Fe-N-C sites. The IIM-Fe-SASC shows better peroxidase-like activities than that of non-imprinted references. Due to its excellent properties, IIM-Fe-SASC is an ideal nanoprobe used in the colorimetric biosensing of hydrogen peroxide (H2O2). Using IIM-Fe-SASC as the nanoprobe, in situ detection of H2O2 generated from MDA-MB-231 cells has been successfully demonstrated with satisfactory sensitivity and specificity. This work opens a novel and easy route in designing advanced SASC and provides a sensitive tool for intracellular H2O2 detection. Supplementary Information The online version contains supplementary material available at 10.1007/s40820-021-00661-z.

Published
2021

6. Promoting Atomically Dispersed MnN4 Sites via Sulfur Doping for Oxygen Reduction: Unveiling Intrinsic Activity and Degradation in Fuel Cells

Author

Maoyu Wang, Hui Xu, Fan Yang, Stavros Karakalos, Guofeng Wang, Xiaoxuan Yang, Lin Guo, Sooyeon Hwang, Gang Wu, Mengjie Chen, Zhenxing Feng, David A. Cullen, and Boyang Li

Subjects
X-ray absorption spectroscopy, Materials science, Dopant, Membrane electrode assembly, Doping, General Engineering, General Physics and Astronomy, 02 engineering and technology, Overpotential, 010402 general chemistry, 021001 nanoscience & nanotechnology, Electrocatalyst, 01 natural sciences, 0104 chemical sciences, Catalysis, Metal, Chemical engineering, visual_art, visual_art.visual_art_medium, General Materials Science, 0210 nano-technology
Abstract

Carbon supported and nitrogen coordinated single Mn site (Mn-N-C) catalysts are the most desirable platinum group metal (PGM)-free cathode catalysts for proton-exchange membrane fuel cells (PEMFCs) due to their insignificant Fenton reactions (vs. Fe), earth abundances (vs. Co), and encouraging activity and stability. However, current Mn-N-C catalysts suffer from high overpotential due to low intrinsic activity and less dense MnN4 sites. Herein, we present a sulfur-doped Mn-N-C catalyst (Mn-N-C-S) synthesized through an effective adsorption-pyrolysis process. Using electron microscopy and X-ray absorption spectroscopy (XAS) techniques, we verify the uniform dispersion of MnN4 sites and confirm the effect of S doping on the Mn-N coordination. The Mn-N-C-S catalyst exhibits a favorable oxygen reduction reaction (ORR) activity in acidic media relative to the S-free Mn-N-C catalyst. The corresponding membrane electrode assembly (MEA) generates enhanced performance with a peak power density of 500 mW cm-2 under a realistic H2/air environment. The constant voltage tests of fuel cells confirm the much-enhanced stability of the Mn-N-C-S catalyst compared to the Fe-N-C and Fe-N-C-S catalysts. The electron microscopy and Fourier transform XAS analyses provide insights into catalyst degradation associated with Mn oxidation and agglomeration. The theoretical calculation elucidates that the promoted ORR activity is mainly attributed to the spatial effect stemmed from the repulsive interaction between the ORR intermediates and adjacent S dopants.

Published
2021

7. Interfacial processes in electrochemical energy systems

Author

Maoyu Wang and Zhenxing Feng

Subjects
Materials science, Metals and Alloys, General Chemistry, Electrolyte, Electrochemistry, Electrochemical energy conversion, Catalysis, Surfaces, Coatings and Films, Electronic, Optical and Magnetic Materials, Ion, Electron transfer, Chemical engineering, Ion adsorption, Desorption, Electrode, Materials Chemistry, Ceramics and Composites
Abstract

Electrochemical energy systems such as batteries, water electrolyzers, and fuel cells are considered as promising and sustainable energy storage and conversion devices due to their high energy densities and zero or negative carbon dioxide emission. However, their widespread applications are hindered by many technical challenges, such as the low efficiency and poor long-term cyclability, which are mostly affected by the changes at the reactant/electrode/electrolyte interfaces. These interfacial processes involve ion/electron transfer, molecular/ion adsorption/desorption, and complex interface restructuring, which lead to irreversible modifications to the electrodes and the electrolyte. The understanding of these interfacial processes is thus crucial to provide strategies for solving those problems. In this review, we will discuss different interfacial processes at three representative interfaces, namely, solid-gas, solid-liquid, and solid-solid, in various electrochemical energy systems, and how they could influence the performance of electrochemical systems.

Published
2021

8. Ultrahigh Oxygen Evolution Reaction Activity Achieved Using Ir Single Atoms on Amorphous CoOx Nanosheets

Author

Qing Zhang, Meng Gu, Maoyu Wang, Xuming Yang, Chao Cai, Xiaotao Zu, Yuanmin Zhu, George E. Sterbinsky, Zhenxing Feng, Duojie Wu, Qi Wang, and Shaobo Han

Subjects
Materials science, Chemical engineering, 010405 organic chemistry, Oxygen evolution, General Chemistry, 010402 general chemistry, 01 natural sciences, Catalysis, Renewable energy storage, 0104 chemical sciences, Amorphous solid
Abstract

Developing efficient electrocatalysts for an oxygen evolution reaction (OER) is important for renewable energy storage. Here, we design high-density Ir single-atom catalysts supported by CoOx amorp...

Published
2020

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

Author

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

Subjects
inorganic chemicals, Materials science, 010405 organic chemistry, chemistry.chemical_element, General Chemistry, Chemical vapor deposition, General Medicine, 010402 general chemistry, Electrocatalyst, Electrochemistry, 01 natural sciences, Nitrogen, Catalysis, 0104 chemical sciences, Metal, chemistry, Chemical engineering, visual_art, visual_art.visual_art_medium, Deposition (phase transition), Platinum
Abstract

Atomically dispersed and nitrogen coordinated single metal sites (M-N-C, M=Fe, Co, Ni, or 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 chemical vapor deposition (CVD) strategy to synthesize the promising single metal site (M-N-C) catalysts. The deposition of gaseous 2-methylimidazole onto ZnO substrates doped with M, followed by an in-situ thermal activation, was proved effective in generating single metal sites well dispersed into porous carbon. In particular, an optimal CVD-derived Fe-N-C catalyst is featured with 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. The CVD synthesis sheds some light on the mass production of single metal site catalysts towards advanced electrocatalysis.

Published
2020

11. Molecular engineering of dispersed nickel phthalocyanines on carbon nanotubes for selective CO2 reduction

Author

Meng Gu, Zhan Jiang, Marcos Lucero, Xiao Zhang, Hongjie Dai, Hailiang Wang, Yang Wang, Zisheng Zhang, Maoyu Wang, Weiying Pan, Jun Li, Yongye Liang, George E. Sterbinsky, Hongzhi Zheng, Zhenxing Feng, Yang-Gang Wang, and Qing Ma

Subjects
Materials science, Gas diffusion electrode, Renewable Energy, Sustainability and the Environment, Energy Engineering and Power Technology, chemistry.chemical_element, 02 engineering and technology, Carbon nanotube, 010402 general chemistry, 021001 nanoscience & nanotechnology, Electrochemistry, 01 natural sciences, 0104 chemical sciences, Electronic, Optical and Magnetic Materials, law.invention, Molecular engineering, Catalysis, Nickel, Fuel Technology, chemistry, Chemical engineering, law, Surface modification, 0210 nano-technology, Selectivity
Abstract

Electrochemical reduction of CO2 is a promising route for sustainable production of fuels. A grand challenge is developing low-cost and efficient electrocatalysts that can enable rapid conversion with high product selectivity. Here we design a series of nickel phthalocyanine molecules supported on carbon nanotubes as molecularly dispersed electrocatalysts (MDEs), achieving CO2 reduction performances that are superior to aggregated molecular catalysts in terms of stability, activity and selectivity. The optimized MDE with methoxy group functionalization solves the stability issue of the original nickel phthalocyanine catalyst and catalyses the conversion of CO2 to CO with >99.5% selectivity at high current densities of up to −300 mA cm−2 in a gas diffusion electrode device with stable operation at −150 mA cm−2 for 40 h. The well-defined active sites of MDEs also facilitate the in-depth mechanistic understandings from in situ/operando X-ray absorption spectroscopy and theoretical calculations on structural factors that affect electrocatalytic performance. Widespread deployment of electrochemical CO2 reduction requires low-cost catalysts that perform well at high current densities. Zhang et al. show that methoxy-functionalized nickel phthalocyanine molecules on carbon nanotubes can operate as high-performing molecularly dispersed electrocatalysts at current densities of up to −300 mA cm–2.

Published
2020

12. Ultrahigh-Loading of Ir Single Atoms on NiO Matrix to Dramatically Enhance Oxygen Evolution Reaction

Author

Maoyu Wang, Qi Wang, Hu Xu, Zhenxing Feng, Jun Li, Meng Gu, Xiang Huang, Zhi Liang Zhao, and Bin Xiang

Subjects
Chemistry, Nickel oxide, Non-blocking I/O, Oxygen evolution, General Chemistry, Overpotential, 010402 general chemistry, Electrocatalyst, 01 natural sciences, Biochemistry, Catalysis, 0104 chemical sciences, Colloid and Surface Chemistry, Chemical engineering, Oxidation state, Density functional theory
Abstract

Engineering single-atom electrocatalysts with high-loading amount holds great promise in energy conversion and storage application. Herein, we report a facile and economical approach to achieve an unprecedented high loading of single Ir atoms, up to ∼18wt%, on the nickel oxide (NiO) matrix as the electrocatalyst for oxygen evolution reaction (OER). It exhibits an overpotential of 215 mV at 10 mA cm-2 and a remarkable OER current density in alkaline electrolyte, surpassing NiO and IrO2 by 57 times and 46 times at 1.49 V vs RHE, respectively. Systematic characterizations, including X-ray absorption spectroscopy and aberration-corrected Z-contrast imaging, demonstrate that the Ir atoms are atomically dispersed at the outermost surface of NiO and are stabilized by covalent Ir-O bonding, which induces the isolated Ir atoms to form a favorable ∼4+ oxidation state. Density functional theory calculations reveal that the substituted single Ir atom not only serves as the active site for OER but also activates the surface reactivity of NiO, which thus leads to the dramatically improved OER performance. This synthesis method of developing high-loading single-atom catalysts can be extended to other single-atom catalysts and paves the way for industrial applications of single-atom catalysts.

Published
2020

13. Stabilizing atomic Pt with trapped interstitial F in alloyed PtCo nanosheets for high-performance zinc-air batteries

Author

Marcos Lucero, Manasi V. Vyas, Nusaiba Zaman, Zhao Li, Hui Cao, Yang Yang, Widitha Samarakoon, Wenhan Niu, Zhenzhong Yang, George E. Sterbinsky, Zhenxing Feng, Abdelkader Kara, Hua Zhou, Yingge Du, and Maoyu Wang

Subjects
Materials science, Renewable Energy, Sustainability and the Environment, Lattice distortion, chemistry.chemical_element, Zinc, Pollution, Oxygen reduction, Catalysis, Nuclear Energy and Engineering, chemistry, Chemical engineering, Fluorine, Environmental Chemistry, Platinum, Cobalt, Power density
Abstract

Recently, considerable attention has been paid to the stabilization of atomic platinum (Pt) catalysts on desirable supports in order to reduce Pt consumption, improve the catalyst stability, and thereafter enhance the catalyst performance in renewable energy devices such as fuel cells and zinc-air batteries (ZABs). Herein, we rationally designed a novel strategy to stabilize atomic Pt catalysts in alloyed platinum cobalt (PtCo) nanosheets with trapped interstitial fluorine (SA-PtCoF) for ZABs. The trapped interstitial F atoms in the PtCoF matrix induce lattice distortion resulting in weakening of the Pt–Co bond, which is the driving force to form atomic Pt. As a result, the onset potentials of SA-PtCoF are 0.95 V and 1.50 V for the oxygen reduction and evolution reactions (ORR and OER), respectively, superior to commercial Pt/C@RuO2. When used in ZABs, the designed SA-PtCoF can afford a peak power density of 125 mW cm−2 with a specific capacity of 808 mA h gZn−1 and excellent cyclability over 240 h, surpassing the state-of-the-art catalysts.

Published
2020

14. Methanol tolerance of atomically dispersed single metal site catalysts: mechanistic understanding and high-performance direct methanol fuel cells

Author

Gang Wu, Macros Lucero, Zhenxing Feng, Yuanyue Liu, Xunhua Zhao, David A. Cullen, Maoyu Wang, Qiurong Shi, Karren L. More, Yanghua He, Xiaowan Bai, and Hua Zhou

Subjects
Materials science, 02 engineering and technology, Electrolyte, 010402 general chemistry, 01 natural sciences, 7. Clean energy, Catalysis, Metal, chemistry.chemical_compound, Adsorption, Environmental Chemistry, Methanol fuel, Renewable Energy, Sustainability and the Environment, 021001 nanoscience & nanotechnology, Pollution, 0104 chemical sciences, Membrane, Nuclear Energy and Engineering, Chemical engineering, chemistry, 13. Climate action, Standard electrode potential, visual_art, visual_art.visual_art_medium, Methanol, 0210 nano-technology
Abstract

Proton-exchange membrane fuel cells (PEMFCs) and direct methanol fuel cells (DMFCs) are promising power sources from portable electronic devices to vehicles. The high-cost issue of these low-temperature fuel cells can be primarily addressed by using platinum-group metal (PGM)-free oxygen reduction reaction (ORR) catalysts, in particular atomically dispersed metal–nitrogen–carbon (M–N–C, M = Fe, Co, Mn). Furthermore, a significant advantage of M–N–C catalysts is their superior methanol tolerance over Pt, which can mitigate the methanol cross-over effect and offer great potential of using a higher concentration of methanol in DMFCs. Here, we investigated the ORR catalytic properties of M–N–C catalysts in methanol-containing acidic electrolytes via experiments and density functional theory (DFT) calculations. FeN4 sites demonstrated the highest methanol tolerance ability when compared to metal-free pyridinic N, CoN4, and MnN4 active sites. The methanol adsorption on MN4 sites is even strengthened when electrode potentials are applied during the ORR. The negative influence of methanol adsorption becomes significant for methanol concentrations higher than 2.0 M. However, the methanol adsorption does not affect the 4e− ORR pathway or chemically destroy the FeN4 sites. The understanding of the methanol-induced ORR activity loss guides the design of promising M–N–C cathode catalyst in DMFCs. Accordingly, we developed a dual-metal site Fe/Co–N–C catalyst through a combined chemical-doping and adsorption strategy. Instead of generating a possible synergistic effect, the introduced Co atoms in the first doping step act as “scissors” for Zn removal in metal–organic frameworks (MOFs), which is crucial for modifying the porosity of the catalyst and providing more defects for stabilizing the active FeN4 sites generated in the second adsorption step. The Fe/Co–N–C catalyst significantly improved the ORR catalytic activity and delivered remarkably enhanced peak power densities (i.e., 502 and 135 mW cm−2) under H2–air and methanol–air conditions, respectively, representing the best performance for both types of fuel cells. Notably, the fundamental understanding of methanol tolerance, along with the encouraging DMFC performance, will open an avenue for the potential application of atomically dispersed M–N–C catalysts in other direct alcohol or ammonia fuel cells.

Published
2020

15. Boosting alkaline hydrogen evolution: the dominating role of interior modification in surface electrocatalysis

Author

Zhenxing Feng, Wenhan Niu, Qi Wang, Yang Yang, Yingge Du, Abdelkader Kara, Maoyu Wang, Zhenzhong Yang, Meng Gu, and Zhao Li

Subjects
Materials science, Electrolysis of water, Renewable Energy, Sustainability and the Environment, Electrochemical kinetics, Electrocatalyst, Pollution, Dissociation (chemistry), Catalysis, Chemical state, Nuclear Energy and Engineering, Chemical engineering, Hydrogen fuel, Environmental Chemistry, Surface modification
Abstract

The alkaline hydrogen evolution reaction (A-HER) holds great promise for clean hydrogen fuel generation but its practical utilization is severely hindered by the sluggish kinetics for water dissociation in alkaline solutions. Traditional ways to improve the electrochemical kinetics for A-HER catalysts have been focusing on surface modification, which still can not meet the demanding requirements for practical water electrolysis because of catalyst surface deactivation. Herein, we report an interior modification strategy to significantly boost the A-HER performance. Specifically, a trace amount of Pt was doped in the interior Co2P (Pt–Co2P) to introduce a stronger dopant–host interaction than that of the surface-modified catalyst. Consequently, the local chemical state and electronic structure of the catalysts were adjusted to improve the electron mobility and reduce the energy barriers for hydrogen adsorption and H–H bond formation. As a proof-of-concept, the interior-modified Pt–Co2P shows a reduced onset potential at near-zero volts for the A-HER, low overpotentials of 2 mV and 58 mV to achieve 10 and 100 mA cm−2, and excellent durability for long-term utilization. The interior-modified Pt–Co2P delivers superior A-HER performance to Pt/C and other state-of-the-art electrocatalysts. This work will open a new avenue for A-HER catalyst design.

Published
2020

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

Author

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

Subjects
Nanostructure, Materials science, Binary number, atomic metal sites, Electrocatalyst, Redox, Oxygen reduction, Catalysis, core−shell structures, oxygen reduction, Metal, Core shell, Chemical engineering, CO2 reduction, visual_art, visual_art.visual_art_medium, TA401-492, electrocatalysis, Materials of engineering and construction. Mechanics of materials
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.

Published
2021

17. Durable and High-Power Iron-Based Cathodes in Competition with Platinum for Proton-Exchange Membrane Fuel Cells

Author

Harry M. Meyer, Qiurong Shi, Boyang Li, Deborah J. Myers, Zhenxing Feng, Michael J. Zachman, David A. Cullen, Shengwen Liu, Yachao Zeng, Litster Shawn, Jonathan Braaten, Jiawei Liu, Haoran Yu, Gang Wu, Maoyu Wang, Marcos Lucero, Qing Gong, A. Jeremy Kropf, Guofeng Wang, Jian Xie, and Chenzhao Li

Subjects
Materials science, Proton exchange membrane fuel cell, chemistry.chemical_element, Electrolyte, Cathode, law.invention, Catalysis, chemistry, Chemical engineering, law, Electrode, Rotating disk electrode, Platinum, Carbon
Abstract

Atomically dispersed and nitrogen-coordinated single iron sites (FeN4) embedded in carbon (Fe-N-C) catalysts are the most promising platinum group metal (PGM)-free catalysts. However, they have yet to match their Pt counterparts for oxygen reduction reaction (ORR) activity and stability in proton exchange membrane fuel cells (PEMFCs). Here, we developed viable Fe-N-C catalysts, which, for the first time, demonstrated competitive activity to that of Pt/C catalysts and dramatically enhanced stability and durability under practical PEMFC operating conditions. The most active Fe-N-C catalyst achieved a record half-wave potential (E1/2 = 0.915 V vs. RHE at 0.6 mgcatcm-2) and an ORR mass activity of 10.5 mA mgcat at 0.9 V in (RDE) tests, exceeding a Pt/C baseline catalyst (60 µgPt cm-2) by 40 mV in acidic electrolytes. This compelling activity of the Fe-N-C catalyst in aqueous acids on rotating disk electrode (RDE) was successfully transferred to a fuel cell membrane electrode assemblies (MEAs), generating an initial current density of 44.2 mA cm-2 exceeding the U.S. DOE 2025 target (i.e., 44 mA cm-2) at 0.9 VIR-free under O2. Under practical hydrogen-air conditions, record 151 mA cm-2 at 0.8 V and peak power density of 601 mW cm-2 were achieved. Importantly, we discovered that depositing nitrogen-carbon species on the catalyst surface via chemical vapor deposition (CVD) dramatically enhanced catalyst stability, evidenced by performance durability after accelerated stress tests (30 000 square-wave voltage cycles under H2/air) and long-term steady-state life tests (> 300 hours at 0.67 V). Innovative identical location-scanning transmission electron microscopy (IL-STEM) experiments confirmed that the CVD process leads to deposition of nitrogen-doped carbon onto the catalyst surfaces. Along with theoretical modeling, a reconstruction of the carbon structure adjacent to FeN4 sites leads to increased robustness against demetallation and carbon oxidation. This work opens new avenues for developing earth-abundant iron-based catalysts with extraordinary activity and stability, thus competing with Pt and addressing the cost barrier of current PEMFCs.

Published
2021

18. Sr3CrN3: A New Electride with a Partially Filled d-Shell Transition Metal

Author

Geoffroy Hautier, Jin Suntivich, Lee A. Burton, Maoyu Wang, Yaroslav Filinchuk, Anatolyi Senyshin, Padtaraporn Chanhom, Kevin E. Fritz, Zhenxing Feng, Jan Kloppenburg, Numpon Insin, UCL - SST/IMCN/MOST - Molecules, Solids and Reactivity, and UCL - SST/IMCN/MODL - Modelling

Subjects
Materials science, Absorption spectroscopy, Nuclear Theory, Neutron diffraction, Ionic crystal, General Chemistry, Free space, Electron, 010402 general chemistry, 01 natural sciences, Biochemistry, Molecular physics, Catalysis, 0104 chemical sciences, chemistry.chemical_compound, Colloid and Surface Chemistry, Atomic orbital, chemistry, Physics::Atomic and Molecular Clusters, Electride
Abstract

Electrides are ionic crystals in which the electrons prefer to occupy free space, serving as anions. Because the electrons prefer to be in the pockets, channels, or layers to the atomic orbitals around the nuclei, it has been challenging to find electrides with partially filled d-shell transition metals, since an unoccupied d-shell provides an energetically favorable location for the electrons to occupy. We recently predicted the existence of electrides with partially filled d-shells using high-throughput computational screening. Here, we provide experimental support using X-ray absorption spectroscopy and X-ray and neutron diffraction to show that Sr3CrN3 is indeed an electride despite its partial d-shell configuration. Our findings indicate that Sr3CrN3 is the first known electride with a partially filled d-shell transition metal, in agreement with theory, which significantly broadens the criteria for the search for new electride materials.

Published
2019

19. Phthalocyanine Precursors To Construct Atomically Dispersed Iron Electrocatalysts

Author

Yang Wang, Qi Wang, Zisheng Zhang, Xing Zhang, Yongye Liang, Marcos Lucero, Maoyu Wang, Zhenxing Feng, Xiaoxiao Li, Meng Gu, and Zhan Jiang

Subjects
Materials science, 010405 organic chemistry, Iron phthalocyanine, chemistry.chemical_element, General Chemistry, 010402 general chemistry, 01 natural sciences, Catalysis, 0104 chemical sciences, Metal, chemistry.chemical_compound, chemistry, Chemical engineering, visual_art, visual_art.visual_art_medium, Phthalocyanine, Oxygen reduction reaction, Carbon, Zeolitic imidazolate framework
Abstract

Carbon materials embedded with atomically dispersed metal sites have recently demonstrated intriguing performance as electrocatalysts. However, it remains challenging to construct abundant single m...

Published
2019

20. Influence of Fe Substitution into LaCoO3 Electrocatalysts on Oxygen-Reduction Activity

Author

Maoyu Wang, Mingyue Zhou, Junjing Deng, Yan Wang, Qing Wang, Marcos Lucero, Binghong Han, Zhichuan J. Xu, Zhenzhen Yang, Yubo Chen, Zhenxing Feng, Alpha T. N'Diaye, and Yi Jiang

Subjects
X-ray absorption spectroscopy, Materials science, chemistry.chemical_element, 02 engineering and technology, 010402 general chemistry, 021001 nanoscience & nanotechnology, Electrocatalyst, Electrochemistry, 01 natural sciences, 0104 chemical sciences, Catalysis, Metal, chemistry, Transition metal, Chemical engineering, visual_art, visual_art.visual_art_medium, General Materials Science, 0210 nano-technology, Platinum, Perovskite (structure)
Abstract

The development of commercially friendly and stable catalysts for oxygen reduction reaction (ORR) is critical for many energy conversion systems such as fuel cells and metal-air batteries. Many Co-based perovskite oxides such as LaCoO3 have been discovered as the stable and active ORR catalysts, which can be good candidates to replace platinum (Pt). Although researchers have tried substituting various transition metals into the Co-based perovskite catalysts to improve the ORR performance, the influence of substitution on the ORR mechanism is rarely studied. In this paper, we explore the evolution of ORR mechanism after substituting Fe into LaCoO3, using the combination of X-ray photoelectron spectroscopy, high-resolution X-ray microscopy, X-ray diffraction, surface-sensitive soft X-ray absorption spectroscopy characterization, and electrochemical tests. We observed enhanced catalytic activities and increased electron transfer numbers during the ORR in Co-rich perovskite, which are attributed to the optimized eg filling numbers and the stronger hybridization of transition metal 3d and oxygen 2p bands. The discoveries in this paper provide deep insights into the ORR catalysis mechanism on metal oxides and new guidelines for the design of Pt-free ORR catalysts.

Published
2019

21. 3D porous graphitic nanocarbon for enhancing the performance and durability of Pt catalysts: a balance between graphitization and hierarchical porosity

Author

Yanghua He, Zhenxing Feng, Zhi Qiao, Mengjie Chen, Jacob S. Spendelow, Maoyu Wang, Widitha Samarakoon, Guofeng Wang, Chenyu Wang, Dong Su, Dongguo Li, Sooyeon Hwang, Hua Zhou, Stavros Karakalos, Zhenyu Liu, Xing Li, and Gang Wu

Subjects
chemistry.chemical_classification, Materials science, Renewable Energy, Sustainability and the Environment, Carbonization, Proton exchange membrane fuel cell, chemistry.chemical_element, 02 engineering and technology, Polymer, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, Pollution, 0104 chemical sciences, Corrosion, Catalysis, Nuclear Energy and Engineering, chemistry, Chemical engineering, Environmental Chemistry, 0210 nano-technology, Porosity, Pyrolysis, Carbon
Abstract

Carbon supports used in oxygen-reduction cathode catalysts for proton exchange membrane fuel cells (PEMFCs) are vulnerable to corrosion under harsh operating conditions, leading to poor performance durability. To address this issue, we have developed highly stable porous graphitic carbon (PGC) produced through pyrolysis of a 3D polymer hydrogel in combination with Mn. The resulting PGC features multilayer carbon sheets assembled in porous and flower-like morphologies. In situ high-temperature electron microscopy was employed to dynamically monitor the carbonization process up to 1100 °C, suggesting that the 3D polymer hydrogel provides high porosity at multiple scales, and that Mn catalyzes the graphitization process more effectively than other metals. Compared to conventional carbon supports such as Vulcan, Ketjenblack, and graphitized carbon, PGC provides an improved balance between high graphitization and hierarchical porosity, which is favorable for uniform Pt nanoparticle dispersion and enhanced corrosion resistance. As a result, Pt supported on PGC exhibits remarkably enhanced stability. In addition to thorough testing in aqueous electrolytes, we also conducted fuel cell testing using durability protocols recommended by the U.S. Department of Energy (DOE). After 5000 voltage cycles from 1.0 to 1.5 V, the Pt/PGC catalyst only lost 9 mV at a current density of 1.5 A cm−2, dramatically exceeding the DOE support durability target (

Published
2019

22. S-Doped MoP Nanoporous Layer Toward High-Efficiency Hydrogen Evolution in pH-Universal Electrolyte

Author

Jose L. Mendoza-Cortes, Kun Liang, Maoyu Wang, George E. Sterbinsky, Zhenxing Feng, Srimanta Pakhira, Licheng Ju, Yang Yang, Yingge Du, A. Nijamudheen, Zhenzhong Yang, and Carlos I. Aguirre-Velez

Subjects
Materials science, 010405 organic chemistry, Nanoporous, Doping, General Chemistry, Electrolyte, 010402 general chemistry, 01 natural sciences, Catalysis, 0104 chemical sciences, Chemical engineering, S doping, Hydrogen evolution, Metal catalyst, Layer (electronics)
Abstract

In this study, we report a nonprecious metal catalyst for high-efficiency hydrogen evolution reaction (HER). A self-organized S-doped MoP nanoporous layer (S-MoP NPL) is achieved through a facile e...

Published
2018

23. Role of surface steps in activation of surface oxygen sites on Ir nanocrystals for oxygen evolution reaction in acidic media

Author

Maoyu Wang, Byung-Hyun Kim, Myeongjin Kim, Hyun-Seok Cho, Qingxiao Wang, Seung Woo Lee, Jinho Park, Jin Young Kim, Moon J. Kim, Chang-Hee Kim, and Zhenxing Feng

Subjects
Materials science, Absorption spectroscopy, Process Chemistry and Technology, Oxygen evolution, Oxide, Catalysis, chemistry.chemical_compound, Membrane, Adsorption, Nanocrystal, chemistry, Chemical engineering, Density functional theory, Surface reconstruction, General Environmental Science
Abstract

Ir and its oxide are the only available oxygen evolution reaction (OER) electrocatalysts with reasonably high activity and stability for commercial proton-exchange membrane electrolyzers. However, the establishment of structure–performance relationships for the design of better Ir-based electrocatalysts is hindered by their uncontrolled surface reconstruction during OER in acidic media. Herein, we monitor the structural evolution of two model Ir nanocrystals (one with a flat surface enclosed by (100) facets and the other with a concave surface containing numerous high-index planes) under acidic OER conditions. Operando X-ray absorption spectroscopy measurements reveal that the promotion of surface IrOx formation during the OER by the concave Ir surface with high-index planes results in a gradual OER activity increase, while a decrease in activity and limited oxide formation are observed for the flat Ir surface. After the activation process, the Ir concave surface exhibits ~ 10 times higher activity than the flat surface. Density functional theory computations reveal that Ir high-index surfaces are thermodynamically preferred for the adsorption of oxygen atoms and the formation of surface oxides under OER conditions. Thus, our work establishes a structure–performance relationship for Ir nanocrystals under operating conditions, providing new principles for the design of nanoscale OER electrocatalysts.

Published
2022

24. Single Cobalt Sites Dispersed in Hierarchically Porous Nanofiber Networks for Durable and High-Power PGM-Free Cathodes in Fuel Cells

Author

Maoyu Wang, David A. Cullen, Jonathan Braaten, Stavros Karakalos, Weitao Shan, Hui Guo, Xiaoxuan Yang, Zhenxing Feng, Ling Fei, Sooyeon Hwang, Guofeng Wang, Dong Su, Hua Zhou, Gang Wu, Zizhou He, Karren L. More, Shawn Litster, and Yanghua He

Subjects
chemistry.chemical_classification, Materials science, Mechanical Engineering, Membrane electrode assembly, Polyacrylonitrile, 02 engineering and technology, Polymer, 010402 general chemistry, 021001 nanoscience & nanotechnology, Electrocatalyst, 7. Clean energy, 01 natural sciences, Electrospinning, 0104 chemical sciences, Catalysis, chemistry.chemical_compound, Chemical engineering, chemistry, Mechanics of Materials, Nanofiber, General Materials Science, 0210 nano-technology, Zeolitic imidazolate framework
Abstract

Increasing catalytic activity and durability of atomically dispersed metal-nitrogen-carbon (M-N-C) catalysts for the oxygen reduction reaction (ORR) cathode in proton-exchange-membrane fuel cells remains a grand challenge. Here, a high-power and durable Co-N-C nanofiber catalyst synthesized through electrospinning cobalt-doped zeolitic imidazolate frameworks into selected polyacrylonitrile and poly(vinylpyrrolidone) polymers is reported. The distinct porous fibrous morphology and hierarchical structures play a vital role in boosting electrode performance by exposing more accessible active sites, providing facile electron conductivity, and facilitating the mass transport of reactant. The enhanced intrinsic activity is attributed to the extra graphitic N dopants surrounding the CoN4 moieties. The highly graphitized carbon matrix in the catalyst is beneficial for enhancing the carbon corrosion resistance, thereby promoting catalyst stability. The unique nanoscale X-ray computed tomography verifies the well-distributed ionomer coverage throughout the fibrous carbon network in the catalyst. The membrane electrode assembly achieves a power density of 0.40 W cm-2 in a practical H2 /air cell (1.0 bar) and demonstrates significantly enhanced durability under accelerated stability tests. The combination of the intrinsic activity and stability of single Co sites, along with unique catalyst architecture, provide new insight into designing efficient PGM-free electrodes with improved performance and durability.

Published
2020

25. Partial-Single-Atom, Partial-Nanoparticle Composites Enhance Water Dissociation for Hydrogen Evolution

Author

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

Subjects
Materials science, Hydrogen, General Chemical Engineering, General Physics and Astronomy, Medicine (miscellaneous), chemistry.chemical_element, single‐atom catalysts, 02 engineering and technology, Overpotential, 010402 general chemistry, Electrocatalyst, 01 natural sciences, Biochemistry, Genetics and Molecular Biology (miscellaneous), Dissociation (chemistry), Catalysis, electrocatalysis, General Materials Science, water dissociation, theoretical calculations, Hydride, Communication, General Engineering, 021001 nanoscience & nanotechnology, Communications, 0104 chemical sciences, chemistry, Chemical engineering, Water splitting, 0210 nano-technology, Faraday efficiency, multiple sites
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 (η 10), 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., A nanocomposite of partial‐single‐atom and partial‐nanoparticle formed within the Fe–N–C matrix serves as a multiple‐site electrocatalyst toward hydrogen evolution reaction with an ultralow overpotential of 9 mV to achieve 10 mA cm−2, a high turnover frequency, and ≈100% Faradaic efficiency. Theoretical calculations reveal that ruthenium single‐atoms effectively facilitate water dissociation, and ruthenium nanoparticles promote hydrogen desorption.

Published
2020

26. Atomically dispersed manganese catalysts for oxygen reduction in proton-exchange membrane fuel cells

Author

Maoyu Wang, Chao Lei, Sooyeon Hwang, Zhen-Bo Wang, David A. Cullen, Hanguang Zhang, Dong Su, Marcos Lucero, Kexi Liu, Karren L. More, Jiazhan Li, Guofeng Wang, Stavros Karakalos, Boyang Li, Hui Xu, Gang Wu, Mengjie Chen, George E. Sterbinsky, and Zhenxing Feng

Subjects
inorganic chemicals, Process Chemistry and Technology, chemistry.chemical_element, Proton exchange membrane fuel cell, Bioengineering, 02 engineering and technology, Manganese, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, Biochemistry, Catalysis, 0104 chemical sciences, Metal, Membrane, chemistry, Chemical engineering, visual_art, visual_art.visual_art_medium, Reversible hydrogen electrode, 0210 nano-technology, Dispersion (chemistry), Carbon
Abstract

Platinum group metal (PGM)-free catalysts that are also iron free are highly desirable for the oxygen reduction reaction (ORR) in proton-exchange membrane fuel cells, as they avoid possible Fenton reactions. Here we report an efficient ORR catalyst that consists of atomically dispersed nitrogen-coordinated single Mn sites on partially graphitic carbon (Mn-N-C). Evidence for the embedding of the atomically dispersed MnN4 moieties within the carbon surface-exposed basal planes was established by X-ray absorption spectroscopy and their dispersion was confirmed by aberration-corrected electron microscopy with atomic resolution. The Mn-N-C catalyst exhibited a half-wave potential of 0.80 V versus the reversible hydrogen electrode, approaching that of Fe-N-C catalysts, along with significantly enhanced stability in acidic media. The encouraging performance of the Mn-N-C catalyst as a PGM-free cathode was demonstrated in fuel cell tests. First-principles calculations further support the MnN4 sites as the origin of the ORR activity via a 4e− pathway in acidic media. Platinum group metal- and iron-free catalysts are highly desirable for the oxygen reduction reaction in proton-exchange membrane fuel cells. Now, Wu and co-workers show a carbon catalyst with atomically dispersed single Mn sites as an efficient catalyst with enhanced stability in acidic media.

Published
2018

27. Unveiling Active Sites of CO2 Reduction on Nitrogen-Coordinated and Atomically Dispersed Iron and Cobalt Catalysts

Author

David A. Cullen, Fuping Pan, Maoyu Wang, Zhenxing Feng, Gang Wu, Ying Li, Kexi Liu, Guofeng Wang, Karren L. More, and Hanguang Zhang

Subjects
Chemistry, chemistry.chemical_element, 02 engineering and technology, General Chemistry, 010402 general chemistry, 021001 nanoscience & nanotechnology, Electrocatalyst, 01 natural sciences, Redox, Nitrogen, Catalysis, Dissociation (chemistry), 0104 chemical sciences, Metal, Crystallography, visual_art, visual_art.visual_art_medium, 0210 nano-technology, Cobalt, Faraday efficiency
Abstract

Herein, we report the exploration of understanding the reactivity and structure of atomically dispersed M–N4 (M = Fe and Co) sites for the CO2 reduction reaction (CO2RR). Nitrogen coordinated Fe or Co site atomically dispersed into carbons (M–N–C) containing bulk- and edge-hosted M–N4 coordination were prepared by using Fe- or Co-doped metal–organic framework precursors, respectively, which were further studied as ideal model catalysts. Fe is intrinsically more active than Co in M–N4 for the reduction of CO2 to CO, in terms of a larger current density and a higher CO Faradaic efficiency (FE) (93% vs. 45%). First principle computations elucidated that the edge-hosted M–N2+2–C8 moieties bridging two adjacent armchair-like graphitic layers is the active sites for the CO2RR. They are much more active than previously proposed bulk-hosted M–N4–C10 moieties embedded compactly in a graphitic layer. During the CO2RR, when the dissociation of *COOH occurs on the M–N2+2–C8, the metal atom is the site for the adsorpt...

Published
2018

28. Single Atomic Iron Catalysts for Oxygen Reduction in Acidic Media: Particle Size Control and Thermal Activation

Author

Chongmin Wang, Stavros Karakalos, Yuyan Shao, Zhi Qiao, Zhenxing Feng, Dong Su, Langli Luo, Gang Wu, Hanguang Zhang, Maoyu Wang, Sooyeon Hwang, and Xiaohong Xie

Subjects
Inorganic chemistry, Proton exchange membrane fuel cell, 02 engineering and technology, General Chemistry, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, Biochemistry, Chemical synthesis, Catalysis, 0104 chemical sciences, Metal, chemistry.chemical_compound, Colloid and Surface Chemistry, chemistry, Nanocrystal, visual_art, Imidazolate, visual_art.visual_art_medium, Particle size, 0210 nano-technology, Zeolitic imidazolate framework
Abstract

It remains a grand challenge to replace platinum group metal (PGM) catalysts with earth-abundant materials for the oxygen reduction reaction (ORR) in acidic media, which is crucial for large-scale deployment of proton exchange membrane fuel cells (PEMFCs). Here, we report a high-performance atomic Fe catalyst derived from chemically Fe-doped zeolitic imidazolate frameworks (ZIFs) by directly bonding Fe ions to imidazolate ligands within 3D frameworks. Although the ZIF was identified as a promising precursor, the new synthetic chemistry enables the creation of well-dispersed atomic Fe sites embedded into porous carbon without the formation of aggregates. The size of catalyst particles is tunable through synthesizing Fe-doped ZIF nanocrystal precursors in a wide range from 20 to 1000 nm followed by one-step thermal activation. Similar to Pt nanoparticles, the unique size control without altering chemical properties afforded by this approach is able to increase the number of PGM-free active sites. The best ORR activity is measured with the catalyst at a size of 50 nm. Further size reduction to 20 nm leads to significant particle agglomeration, thus decreasing the activity. Using the homogeneous atomic Fe model catalysts, we elucidated the active site formation process through correlating measured ORR activity with the change of chemical bonds in precursors during thermal activation up to 1100 °C. The critical temperature to form active sites is 800 °C, which is associated with a new Fe species with a reduced oxidation number (from Fe

Published
2017

29. Electroreduction of CO2 Catalyzed by a Heterogenized Zn–Porphyrin Complex with a Redox-Innocent Metal Center

Author

Gary W. Brudvig, Yueshen Wu, Yiren Zhong, Jianbing Jiang, Maoyu Wang, Zhe Weng, Hailiang Wang, Zhenxing Feng, and Daniël L. J. Broere

Subjects
Standard hydrogen electrode, Ligand, General Chemical Engineering, Inorganic chemistry, 02 engineering and technology, General Chemistry, 010402 general chemistry, 021001 nanoscience & nanotechnology, Photochemistry, Electrochemistry, Electrocatalyst, 01 natural sciences, Porphyrin, Redox, 0104 chemical sciences, Catalysis, lcsh:Chemistry, chemistry.chemical_compound, chemistry, lcsh:QD1-999, Cyclic voltammetry, 0210 nano-technology, Research Article
Abstract

Transition-metal-based molecular complexes are a class of catalyst materials for electrochemical CO2 reduction to CO that can be rationally designed to deliver high catalytic performance. One common mechanistic feature of these electrocatalysts developed thus far is an electrogenerated reduced metal center associated with catalytic CO2 reduction. Here we report a heterogenized zinc–porphyrin complex (zinc(II) 5,10,15,20-tetramesitylporphyrin) as an electrocatalyst that delivers a turnover frequency as high as 14.4 site–1 s–1 and a Faradaic efficiency as high as 95% for CO2 electroreduction to CO at −1.7 V vs the standard hydrogen electrode in an organic/water mixed electrolyte. While the Zn center is critical to the observed catalysis, in situ and operando X-ray absorption spectroscopic studies reveal that it is redox-innocent throughout the potential range. Cyclic voltammetry indicates that the porphyrin ligand may act as a redox mediator. Chemical reduction of the zinc–porphyrin complex further confirms that the reduction is ligand-based and the reduced species can react with CO2. This represents the first example of a transition-metal complex for CO2 electroreduction catalysis with its metal center being redox-innocent under working conditions., A zinc−porphyrin complex, with the redox-innocent Zn ion binding reaction intermediates and the ligand mediating electron transfer, catalyzes CO2 electroreduction to CO in high Faradaic efficiency.

Published
2017

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

Author

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

Subjects
Materials science, Nanostructure, Process Chemistry and Technology, Membrane electrode assembly, Proton exchange membrane fuel cell, 02 engineering and technology, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, Catalysis, Cathode, 0104 chemical sciences, law.invention, Membrane, Chemical engineering, law, Particle, 0210 nano-technology, Dispersion (chemistry), General Environmental Science
Abstract

Atomically dispersed and nitrogen coordinated single iron site (i.e., FeN4) 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 FeN4 sites due to the inevitable agglomeration of particles in cathodes. Herein, we report a self-assembled strategy to synthesize the atomically dispersed FeN4 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.

Published
2020

31. In Situ X-Ray Absorption Spectroscopy Studies of Co9S8 Catalyst in Oxygen Evolution Reaction

Author

Zhenxing Feng and Maoyu Wang

Subjects
In situ, X-ray absorption spectroscopy, Materials science, Oxygen evolution, Photochemistry, Catalysis
Abstract

Transition metal sulphide are made from earth-abundant elements and show promising activity for oxygen evolution reaction for water splitting to generate clean fuels. However, these catalysts usually restructure to different composition and/or structure that are distinct from their initial states. Ex-situ characterizations on the such catalysts before and after reaction do not provide the meaning structure-property relationship. Therefore, it is necessary to use in-situ techniques to characterize catalysts in reactions. In this talk, I will show our recent work on Co9S8 which exhibits higher OER activity than RuO2. Using several in-situcharacterizations, particularly X-ray absorption spectroscopy (XAS), we not only directly observe how catalysts adjust their local structures and valence state to promote OER, but also identify the true reaction center. With help from density functional theory, we show that the di-m-oxo bridged Co-Co motif is the active site, which can be used for catalyst designs.

Published
2020

32. Atomically Dispersed Single Ni Site Catalysts for Nitrogen Reduction toward Electrochemical Ammonia Synthesis Using N 2 and H 2 O

Author

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

Subjects
Materials science, Inorganic chemistry, chemistry.chemical_element, 02 engineering and technology, General Chemistry, 010402 general chemistry, 021001 nanoscience & nanotechnology, Electrochemistry, Electrocatalyst, 01 natural sciences, Nitrogen, 0104 chemical sciences, Catalysis, Reduction (complexity), Ammonia production, chemistry, General Materials Science, Metal-organic framework, 0210 nano-technology
Published
2020

33. Active sites of copper-complex catalytic materials for electrochemical carbon dioxide reduction

Author

Zhenxing Feng, Zhe Weng, Gary W. Brudvig, Hailiang Wang, Jianbing Jiang, Ke R. Yang, Shengjuan Huo, Xiao Feng Wang, Maoyu Wang, Victor S. Batista, Qing Ma, Yongye Liang, and Yueshen Wu

Subjects
Materials science, Science, Inorganic chemistry, General Physics and Astronomy, chemistry.chemical_element, 02 engineering and technology, 010402 general chemistry, Electrochemistry, Electrocatalyst, 01 natural sciences, Article, General Biochemistry, Genetics and Molecular Biology, Catalysis, chemistry.chemical_compound, lcsh:Science, Electrochemical reduction of carbon dioxide, Multidisciplinary, General Chemistry, 021001 nanoscience & nanotechnology, Copper, 0104 chemical sciences, chemistry, Phthalocyanine, Reversible hydrogen electrode, lcsh:Q, 0210 nano-technology, Carbon
Abstract

Restructuring-induced catalytic activity is an intriguing phenomenon of fundamental importance to rational design of high-performance catalyst materials. We study three copper-complex materials for electrocatalytic carbon dioxide reduction. Among them, the copper(II) phthalocyanine exhibits by far the highest activity for yielding methane with a Faradaic efficiency of 66% and a partial current density of 13 mA cm−2 at the potential of – 1.06 V versus the reversible hydrogen electrode. Utilizing in-situ and operando X-ray absorption spectroscopy, we find that under the working conditions copper(II) phthalocyanine undergoes reversible structural and oxidation state changes to form ~ 2 nm metallic copper clusters, which catalyzes the carbon dioxide-to-methane conversion. Density functional calculations rationalize the restructuring behavior and attribute the reversibility to the strong divalent metal ion–ligand coordination in the copper(II) phthalocyanine molecular structure and the small size of the generated copper clusters under the reaction conditions., The catalytic conversion of carbon dioxide into value-added products requires an understanding of the active species present under working conditions. Here, the authors discover copper-containing complexes to reversibly transform during electrocatalysis into methane-producing copper nanoclusters.

Published
2018

34. Nitrogen‐Coordinated Single Cobalt Atom Catalysts for Oxygen Reduction in Proton Exchange Membrane Fuel Cells

Author

Yanghua He, Yung Tin Pan, Zhenxing Feng, Mark H. Engelhard, David A. Cullen, Maoyu Wang, Yuyan Shao, Jingyun Wang, Jacob S. Spendelow, Sooyeon Hwang, Dong Su, Hanguang Zhang, Gang Wu, Xiao Xia Wang, and Karren L. More

Subjects
inorganic chemicals, Materials science, Mechanical Engineering, Radical, Inorganic chemistry, Proton exchange membrane fuel cell, 02 engineering and technology, 010402 general chemistry, 021001 nanoscience & nanotechnology, Electrocatalyst, 01 natural sciences, Peroxide, Cathode, 0104 chemical sciences, law.invention, Catalysis, chemistry.chemical_compound, Membrane, chemistry, Mechanics of Materials, law, Reversible hydrogen electrode, General Materials Science, 0210 nano-technology
Abstract

Due to the Fenton reaction, the presence of Fe and peroxide in electrodes generates free radicals causing serious degradation of the organic ionomer and the membrane. Pt-free and Fe-free cathode catalysts therefore are urgently needed for durable and inexpensive proton exchange membrane fuel cells (PEMFCs). Herein, a high-performance nitrogen-coordinated single Co atom catalyst is derived from Co-doped metal-organic frameworks (MOFs) through a one-step thermal activation. Aberration-corrected electron microscopy combined with X-ray absorption spectroscopy virtually verifies the CoN4 coordination at an atomic level in the catalysts. Through investigating effects of Co doping contents and thermal activation temperature, an atomically Co site dispersed catalyst with optimal chemical and structural properties has achieved respectable activity and stability for the oxygen reduction reaction (ORR) in challenging acidic media (e.g., half-wave potential of 0.80 V vs reversible hydrogen electrode (RHE). The performance is comparable to Fe-based catalysts and 60 mV lower than Pt/C -60 μg Pt cm-2 ). Fuel cell tests confirm that catalyst activity and stability can translate to high-performance cathodes in PEMFCs. The remarkably enhanced ORR performance is attributed to the presence of well-dispersed CoN4 active sites embedded in 3D porous MOF-derived carbon particles, omitting any inactive Co aggregates.

Published
2018

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