Ultra-thin layer structured anodes for highly durable low-Pt direct formic acid fuel cells

Wang, Rongyue; Liu, Jianguo; Liu, Pan; Bi, Xuanxuan; Yan, Xianliang; Wang, Wenxin; Meng, Yifei; Ge, Xingbo; Ding, Yi

doi:10.1007/s12274-014-0517-9

Cited by 53 publications

(36 citation statements)

References 45 publications

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“…None diffraction peaks presented to Al-based materials indicates that Al constituent has been completely removed by using the dealloying method. Significantly different from the typical nanoporous structure by using dealloying method, [36,37,40,41] Figure 2a Figure 2c-d could be indexed to CuO which is consistent with the XRD analysis. According to the XRD patterns, it must be mentioned that none compounds containing Pd are detected in Cu 18 Pd 2 Al 80 as well as that in (Cu 0.9 Pd 0.1 )O.…”

Section: Resultssupporting

confidence: 80%

CuPd Alloy Oxide Nanobelts as Electrocatalyst Towards Hydrazine Oxidation

2019

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Among non-precious metal catalysts for the hydrazine oxidation reaction, Cu-based catalysts have exhibited relatively high performance ascribed to their lower onset potential and better stability. However, the catalytic properties, including activity and durability, still need further improvement in contrast to noble metal catalysts such as Pt and Pd. In this study, Pd was used as the promotor between Cu and Pd towards the hydrazine oxidation reaction. The CuPd alloy oxide ((Cu 0.9 Pd 0.1 ) O) nanobelts were fabricated by using a dealloying method. The electrochemical measurements show that (Cu 0.9 Pd 0.1 )O nanobelts exhibit 1.5 times higher current density, and better stability than CuO towards the hydrazine electro-oxidation reaction. These improvements are further evidenced in the direct hydrazine-hydrogen peroxide fuel cell by using these two catalysts as the anodes in comparison. A single fuel cell using (Cu 0.9 Pd 0.1 )O as the anode exhibits a peak power density of 330 mW cm À 2 , about 100 mW cm À 2 higher than that of pure CuO. N 2 sorption experiments and product analysis demonstrate that alloying with Pd not only could enlarge the surface area of (Cu 0.9 Pd 0.1 )O but also could suppress the self-decomposition of hydrazine. These improvements will consequently increase the catalytic activity and fuel efficiency of (Cu 0.9 Pd 0.1 )O.

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Section: Resultssupporting

confidence: 80%

CuPd Alloy Oxide Nanobelts as Electrocatalyst Towards Hydrazine Oxidation

2019

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“…Therefore, studies focusing on exploring pollution-free energy production, conversion and storage devices have attracted a large number of investigators678. With the features of nontoxic, non-flammable, high energy density and abundant resource of glucose, direct glucose fuel cell (DGFC) is a promising energy conversion device9101112.…”

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confidence: 99%

Pt-Bi decorated nanoporous gold for high performance direct glucose fuel cell

Hong

Yin

Yan

et al. 2016

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Binary PtBi decorated nanoporous gold (NPG-PtBi) electrocatalyst is specially designed and prepared for the anode in direct glucose fuel cells (DGFCs). By using electroless and electrochemical plating methods, a dense Pt layer and scattered Bi particles are sequentially coated on NPG. A simple DGFC with NPG-PtBi as anode and commercial Pt/C as cathode is constructed and operated to study the effect of operating temperatures and concentrations of glucose and NaOH. With an anode noble metal loading of only 0.45 mg cm−2 (Au 0.3 mg and Pt 0.15 mg), an open circuit voltage (OCV) of 0.9 V is obtained with a maximum power density of 8 mW cm−2. Furthermore, the maximum gravimetric power density of NPG-PtBi is 18 mW mg−1, about 4.5 times higher than that of commercial Pt/C.

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“…EIS results were in accordance with CV and CA results. Although the explanations about the mechanism of FAE reaction on the surface of Pd are 0controversial, researchers suggest that the carbonaceous compounds, ─OH and ─COOH groups, poison the surface of Pd . Moreover, it was reported by Zhou et al that poisoning tolerance was enhanced with the increase of charge transfer resistance.…”

Section: Resultsmentioning

confidence: 99%

Determination of optimum Pd:Ni ratio for Pd _x Ni _{100‐
x} / CNT s formic acid electrooxidation catalysts synthesized via sodium borohydride reduction method

2019

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Summary The main purpose of this study is to investigate the optimum Pd:Ni molar ratio for carbon nanotube–supported PdNi (PdxNi100‐x/CNT) alloy catalysts toward formic acid electrooxidation (FAE). NaBH4 reduction method was employed for the synthesis of Pd90Ni10/CNT, Pd70Ni30/CNT, Pd50Ni50/CNT, and Pd40Ni60/CNT. Synthesized catalysts were characterized by employing advanced surface analytical techniques, namely, X‐ray diffraction (XRD), transmission electron microscopy (TEM), N2 adsorption‐desorption, and inductively coupled plasma–mass spectrometry (ICP‐MS). The characterization results showed that all catalysts were successfully synthesized at desired molar composition. Pd90Ni10/CNT displayed the highest specific and mass activities with 2.32 mA/cm2 and 613.9 mA/mg Pd, respectively. Specific activity of the Pd90Ni10/CNT was found approximately 3.6, 2.3, 11.1, and 3.4 times higher than those of Pd70Ni30/CNT, Pd50Ni50/CNT, Pd40Ni60/CNT, and Pd/CNT, respectively. The synergistic effect between Pd and Ni at optimized metal ratio was utilized to obtain an improvement in specific activity. Furthermore, Pd90Ni10/CNT showed the lowest charge transfer resistance (Rct) and a long‐term stability. To our knowledge, this is the first study reporting the optimization of atomic molar composition for PdxNi100‐x/CNT catalysts toward FAE.

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Ultra-thin layer structured anodes for highly durable low-Pt direct formic acid fuel cells

Cited by 53 publications

References 45 publications

CuPd Alloy Oxide Nanobelts as Electrocatalyst Towards Hydrazine Oxidation

CuPd Alloy Oxide Nanobelts as Electrocatalyst Towards Hydrazine Oxidation

Pt-Bi decorated nanoporous gold for high performance direct glucose fuel cell

Determination of optimum Pd:Ni ratio for Pd _x Ni _{100‐
x} / CNT s formic acid electrooxidation catalysts synthesized via sodium borohydride reduction method

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Ultra-thin layer structured anodes for highly durable low-Pt direct formic acid fuel cells

Cited by 53 publications

References 45 publications

CuPd Alloy Oxide Nanobelts as Electrocatalyst Towards Hydrazine Oxidation

CuPd Alloy Oxide Nanobelts as Electrocatalyst Towards Hydrazine Oxidation

Pt-Bi decorated nanoporous gold for high performance direct glucose fuel cell

Determination of optimum Pd:Ni ratio for Pd x Ni 100‐ x / CNT s formic acid electrooxidation catalysts synthesized via sodium borohydride reduction method

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Product

Resources

About

Determination of optimum Pd:Ni ratio for Pd _x Ni _{100‐
x} / CNT s formic acid electrooxidation catalysts synthesized via sodium borohydride reduction method