High Performance 3D Self‐Supporting Cu−Bi Aerogels for Electrocatalytic Reduction of CO<sub>2</sub> to Formate

Li, Huaxin; Yue, Xian; Che, Jianfei; Xiao, Zuoyi; Yu, Xianbo; Sun, Fenglei; Xue, Chao; Xiang, Jinjuan

doi:10.1002/cssc.202200226

Cited by 22 publications

(16 citation statements)

References 58 publications

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“…The AuX alloy aerogels were synthesized with metal precursors of Au and X (X = Ga, Ni, Mo, Zn, Cr) in the presence of NaBH 4 as the reducing agent. Notably, the self-assembly process of the AuX hydrogels was obtained by standing for 3 h at 60 °C, which is shorter than the recently reported metal aerogels. − Then, the hydrogels were dried by a freeze-drying method to obtain three-dimensional porous metal aerogels. Finally, the AuX aerogels were dripped onto carbon paper to serve as the working electrodes for the electroreduction of CO 2 .…”

Section: Resultsmentioning

confidence: 99%

Synthesis of AuX (X = Ni, Ga, Mo, Zn, and Cr) Alloy Aerogels as High-Performance Electrocatalytic CO₂ Reduction Reaction Catalysts

et al. 2023

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Electrocatalytic CO2 reduction reaction (eCO2RR) into value-added chemicals is highly desirable to mitigate the global warming effect and energy crisis. Metal aerogels, as featured by a self-supporting structure, large specific surface area, outstanding conductivity, and a hierarchical porous structure, are ideal electrocatalysts in eCO2RR. Herein, we report a simple and general strategy for constructing a series of Au-based alloy aerogels which contain Au with another metal including Ga, Ni, Mo, Zn, and Cr, respectively. For the first time, the electrocatalytic activities of AuGa aerogels, AuNi aerogels, and AuMo aerogels for CO2RR were studied in detail. The resultant Au81Ga19 aerogel achieves a 95.2% Faradaic efficiency (FE) at −1.16 V versus reversible hydrogen (vs RHE) in H-cells. Impressively, a total 99.4% FE for C1 products (CO + HCOOH) with a current density of 100 mA cm–2 at −0.6 V vs RHE and a large current density of 228 mA cm–2 can be achieved at −0.9 V with a 72.3% FE for the C1 product in a flow cell. Electrochemical characterization and theoretical calculations further revealed that the outstanding performance of the Au-based aerogels was derived from the large specific surface area, abundant grain boundaries, low interfacial charge transfer resistance, and synergetic effect. Overall, this study provides a promising alternative to engineer alloy aerogel electrocatalysts for highly efficient CO2 electroreduction.

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Section: Resultsmentioning

confidence: 99%

Synthesis of AuX (X = Ni, Ga, Mo, Zn, and Cr) Alloy Aerogels as High-Performance Electrocatalytic CO₂ Reduction Reaction Catalysts

et al. 2023

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“…In this regard, effective strategies to ensure uneven catalyst surfaces, such as arranging specific atomic structures or mixing multiple elements, should be considered (Tables 2 and 3). Single-metal aerogel Au CO 2 !CO 95.6 %, À 0.5 V vs. RHE À 15.10 mA cm À 2 ; À 0.59 V vs. RHE [138] Multi-metal-doped aerogel AgÀ Cu CO 2 !CO 89.4 %, À 0.89 V vs. RHE À 5.86 mA cm À 2 ; À 0.89 V vs. RHE [67] CuÀ Bi CO 2 !HCOOH 96.57 %, À 0.90 V vs. RHE À 10.72 mA cm À 2 ; À 0.90 V vs. RHE [113] BiÀ Sn CO 2 !HCOOH 93.9 %, À 1.00 V vs. RHE À 9.30 mA cm À 2 ; À 1.00 V vs. RHE [68] PdÀ Cu CO 2 !CH 3 OH 80.0 %, À 2.10 V vs. Ag/Ag + À 31.80 mA cm À 2 ; À 2.10 V vs. Ag/Ag + [99] Au-Pd CO 2 !CO 99.96 %, À 0.50 V vs. RHE Not reported [139] NÀ P-Co CO 2 !CO 99.1 %, À 2.40 V vs. Ag/Ag + À 143.60 mA cm À 2 ; À 2.40 V vs. RHE [140] Nano-metal-doped carbon aerogel Cu-Ag CO 2 !CO 71.00 %, À 1.26 V vs. RHE À 15.77 mA cm À 2 ; À 1.26 V vs. RHE [141] Cu NPs CO 2 !CO 75.60 %, À 0.60 V vs. RHE À 5.00 mA cm À 2 ; À 0.60 V vs. RHE [142] Ni-N CO 2 !CO 98.00 %, À 0.80 V vs. RHE À 15.16 mA cm À 2 ; À 1.00 V vs. RHE [126] Ni-N CO 2 !CO 90.20 %, À 0.80 V vs. RHE Not reported [143] Chemistry-A European Journal 1) Among single non-precious metals, Zn is the most promising economic catalyst for the production of CO and is an abundant transition metal on Earth. [128] Although Zn is less active than Au or Ag in making CO, recent reports suggest that its activity can be enhanced by materials engineering, such as nanostructuring, preparation of Zn-based compounds, and combination with other materials.…”

Section: Discussionmentioning

confidence: 99%

“…This is mainly due to the existence of CuBiO 4 crystals in CuBi aerogels, which also proves that the synergistic effect of CuBi improves the electrocatalytic activity of aerogels for CO 2 . After 36 h of continuous catalysis, the TEM images show that the catalyst still maintains a self‐supporting porous structure, indicating the excellent structural stability of CuBi aerogels (Figure 5e, f) [113] …”

Section: Metallic Aerogels: Properties and Synthesis Methodsmentioning

confidence: 99%

“…After 36 h of continuous catalysis, the TEM images show that the catalyst still maintains a self-supporting porous structure, indicating the excellent structural stability of CuBi aerogels (Figure 5e, f). [113] Wu et al mixed Bi(NO 3 ) 3 , SnCl 2 and NaBH 4 at 60 °C for 12 h, and then freeze-dried BiSn aerogels composed entirely of nontransition metal elements for the first time. Compared with single Bi or Sn aerogel, the BiSn aerogel exposes more active sites, and the mass transfer performance is further enhanced, which endows a Faraday efficiency of 93.9 % of HCOOH.…”

Section: Non-noble Metal-doped Aerogel For Co 2 Reductionmentioning

confidence: 99%

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Metal‐Based Aerogels Catalysts for Electrocatalytic CO₂ Reduction

Wang

Yang

et al. 2022

Chemistry A European J

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General strategies for metal aerogel synthesis, including single-metal, transition-metal doped, multi-metaldoped, and nano-metal-doped carbon aerogel are described. In addition, the latest applications of several of the abovementioned metal aerogels in electrocatalytic CO 2 reduction are discussed. Finally, considering the possibility of future applications of electrocatalytic CO 2 reduction technology, a vision for industrialization and directions that can be optimized are proposed.According to the available studies, copper is the only recognized multiphase catalyst for electrocatalytic CO 2 reduction to generate various hydrocarbons and their oxides, such as ethanol and ethylene. [61] Therefore, this review explores the mechanism of CO 2 reduction by electrocatalytic reduction of CO 2 on the surface of copper-based catalysts. On the basis of coordination chemistry, the reduction process of CO 2 is controlled by several steps. These steps include the transfer of two, six, eight and twelve electrons, corresponding to the common products CO, CH 3 OH, CH 4 , C 2 H 4 and C 2 H 5 OH (Table 1). [62][63][64][65] Electrocatalytic CO 2 reduction reactions usually [a] Y.

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“…Li et al prepared Cu/Bi aerogels with enhanced eCO 2 RR activity using a simple one‐step assembly method. [ 197 ] At a potential of −0.9 V versus RHE, the Cu 1 Bi 2 catalyst exhibits excellent eCO 2 RR activity with a FE of 96.57% towards HCOOH, and the FE of HCOOH remains over 80.18% over a wide potential range (−0.8 to −1.2 V vs RHE). The increased eCO 2 RR activity is due to the self‐supporting structure and synergistic effect of Cu and Bi.…”

Section: Advanced Electrocatalysts For Cathodic Reactionsmentioning

confidence: 99%

Electro‐Synthesis of Organic Compounds with Heterogeneous Catalysis

et al. 2022

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Electro-organic synthesis has attracted a lot of attention in pharmaceutical science, medicinal chemistry, and future industrial applications in energy storage and conversion. To date, there has not been a detailed review on electro-organic synthesis with the strategy of heterogeneous catalysis. In this review, the most recent advances in synthesizing value-added chemicals by heterogeneous catalysis are summarized. An overview of electrocatalytic oxidation and reduction processes as well as paired electrocatalysis is provided, and the anodic oxidation of alcohols (monohydric and polyhydric), aldehydes, and amines are discussed. This review also provides in-depth insight into the cathodic reduction of carboxylates, carbon dioxide, C=C, C≡C, and reductive coupling reactions. Moreover, the electrocatalytic paired electro-synthesis methods, including parallel paired, sequential divergent paired, and convergent paired electrolysis, are summarized. Additionally, the strategies developed to achieve high electrosynthesis efficiency and the associated challenges are also addressed. It is believed that electro-organic synthesis is a promising direction of organic electrochemistry, offering numerous opportunities to develop new organic reaction methods.

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High Performance 3D Self‐Supporting Cu−Bi Aerogels for Electrocatalytic Reduction of CO₂ to Formate

Cited by 22 publications

References 58 publications

Synthesis of AuX (X = Ni, Ga, Mo, Zn, and Cr) Alloy Aerogels as High-Performance Electrocatalytic CO₂ Reduction Reaction Catalysts

Synthesis of AuX (X = Ni, Ga, Mo, Zn, and Cr) Alloy Aerogels as High-Performance Electrocatalytic CO₂ Reduction Reaction Catalysts

Metal‐Based Aerogels Catalysts for Electrocatalytic CO₂ Reduction

Electro‐Synthesis of Organic Compounds with Heterogeneous Catalysis

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High Performance 3D Self‐Supporting Cu−Bi Aerogels for Electrocatalytic Reduction of CO2 to Formate

Cited by 22 publications

References 58 publications

Synthesis of AuX (X = Ni, Ga, Mo, Zn, and Cr) Alloy Aerogels as High-Performance Electrocatalytic CO2 Reduction Reaction Catalysts

Synthesis of AuX (X = Ni, Ga, Mo, Zn, and Cr) Alloy Aerogels as High-Performance Electrocatalytic CO2 Reduction Reaction Catalysts

Metal‐Based Aerogels Catalysts for Electrocatalytic CO2 Reduction

Electro‐Synthesis of Organic Compounds with Heterogeneous Catalysis

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Product

Resources

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High Performance 3D Self‐Supporting Cu−Bi Aerogels for Electrocatalytic Reduction of CO₂ to Formate

Synthesis of AuX (X = Ni, Ga, Mo, Zn, and Cr) Alloy Aerogels as High-Performance Electrocatalytic CO₂ Reduction Reaction Catalysts

Synthesis of AuX (X = Ni, Ga, Mo, Zn, and Cr) Alloy Aerogels as High-Performance Electrocatalytic CO₂ Reduction Reaction Catalysts

Metal‐Based Aerogels Catalysts for Electrocatalytic CO₂ Reduction