Electrocatalytic oxygen reduction on single-walled carbon nanotubes supported Pt alloys nanoparticles in acidic and alkaline conditions

Golikand, Ahmad Nozad; Asgari, Mehdi; Lohrasbi, Elaheh; Yari, Mohammad

doi:10.1007/s10800-009-9812-7

Cited by 14 publications

(11 citation statements)

References 44 publications

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“…23 An acid treatment process (glacial acetic acid, 2 hours) increases the hydrophilicity of the CNT-textile and creates oxygen-rich functional groups on the originally inert CNT surface acting as nucleating sites for Pt deposition. 27,28 Then the electrochemical deposition process was performed in a flask containing chloroplatinic acid (H 2 PtCl 6 , 0.019 M) and hydrochloric acid (HCl, 0.6 M) as electrolyte, by fixing the potential of CNT-textile at À0.6 V vs. a double junction Ag|AgCl|KCl (3.5 M) reference electrode (RE) and limiting the charge at 600 mC. 27 Fig.…”

Section: Broader Contextmentioning

confidence: 99%

Nano-structured textiles as high-performance aqueous cathodes for microbial fuel cells

Xie

Pasta

et al. 2011

Energy Environ. Sci.

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A carbon nanotube (CNT)-textile-Pt cathode for aqueous-cathode microbial fuel cells (MFCs) was prepared by electrochemically depositing Pt nanoparticles on a CNT-textile. An MFC equipped with a CNT-textile-Pt cathode revealed a 2.14-fold maximum power density with only 19.3% Pt loading, compared to that with a commercial Pt coated carbon cloth cathode.Microbial fuel cell (MFC) technology is promising for wastewater treatment because it enables recovery of clean electric energy as wastewater organic matter is oxidized. [1][2][3][4] The preferred oxidant is the oxygen in air because it is cheap and readily available, 5,6 but the efficiency of oxygen reduction is constrained by operating conditions (low oxygen solubility, temperature and mostly neutral pH). 5,7,8 Consequently, cathode performance often limits MFC power output. 7,9 In addition, the cathode usually accounts for the greatest part of the capital cost of a MFC, due to the use of expensive metal catalysts, such as Pt. 10 Improving cathode performance and driving down cathode costs are therefore critical. 5 According to the different cathode configurations, MFCs are classified into two categories: aqueous-cathode MFCs and aircathode MFCs. In an aqueous-cathode MFC, the cathode is immerged in an electrolyte purged with air, thus oxygen dissolved in the electrolyte works as an electron acceptor, 7 while for an aircathode MFC, one side of the cathode is directly exposed to air and gas phase oxygen is reduced. 4 A common opinion is that aqueouscathode MFCs do not perform as well as air-cathode MFCs. 2 However, most of the previous studies on aqueous-cathode MFCs employed cathodes prepared by coating a carbon supported catalyst paste onto a carbon cloth (CC) substrate. 7,[11][12][13][14][15] This cathode configuration, widely used in chemical fuel cells, is actually designed for oxygen reduction in the gas phase. An aqueous-cathode MFC may also achieve high performance if the cathode can be well designed for reduction of oxygen dissolved in the electrolyte. In the case of an aircathode MFC where an aqueous electrolyte is only on the anode side, the separator or separator/cathode composite needs to be strong enough to withstand the hydrostatic pressure. This is a challenge for air-cathode MFCs at large scales. However, the requirements on mechanical properties are much lower for the separator in an aqueous-cathode MFC because both sides of the separator are filled with aqueous electrolyte. Moreover, some modified MFC

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Section: Broader Contextmentioning

confidence: 99%

Nano-structured textiles as high-performance aqueous cathodes for microbial fuel cells

Xie

Pasta

et al. 2011

Energy Environ. Sci.

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“…Pt-based nanoparticles have been extensively studied as electrocatalysts for the oxygen reduction reaction (ORR) in both acid and alkaline media 1 2 3 4 5 6 7 . However, the high cost and the limited reserve of Pt hinder the widespread deployment of fuel-cell technologies.…”

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confidence: 99%

Spontaneous incorporation of gold in palladium-based ternary nanoparticles makes durable electrocatalysts for oxygen reduction reaction

et al. 2016

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Replacing platinum by a less precious metal such as palladium, is highly desirable for lowering the cost of fuel-cell electrocatalysts. However, the instability of palladium in the harsh environment of fuel-cell cathodes renders its commercial future bleak. Here we show that by incorporating trace amounts of gold in palladium-based ternary (Pd6CoCu) nanocatalysts, the durability of the catalysts improves markedly. Using aberration-corrected analytical transmission electron microscopy in conjunction with synchrotron X-ray absorption spectroscopy, we show that gold not only galvanically replaces cobalt and copper on the surface, but also penetrates through the Pd–Co–Cu lattice and distributes uniformly within the particles. The uniform incorporation of Au provides a stability boost to the entire host particle, from the surface to the interior. The spontaneous replacement method we have developed is scalable and commercially viable. This work may provide new insight for the large-scale production of non-platinum electrocatalysts for fuel-cell applications.

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“…One is direct four electron O 2 reduction in water (rate constant k 1 ) without the intermediate formation of HO 2 − , ad. The second possible pathway is a 2‐electron reduction of HO 2 − (rate constant k 2 ), which can be either a final product (rate constant k 3 ), or further be reduced to OH − ( k 4 ), ie, the so‐called serial four electron pathway …”

Section: Resultsmentioning

confidence: 99%

“…The second possible pathway is a 2-electron reduction of HO 2 − (rate constant k 2 ), which can be either a final product (rate constant k 3 ), or further be reduced to OH − (k 4 ), ie, the so-called serial four electron pathway. 23 In this interaction, the effect of pH can be shown according to Equation 3.4. The studies have shown that as the basicity increases (pH), the oxygen reduction region shifts to the negative.…”

Section: Resultsmentioning

confidence: 99%

The behavior of chemical and electrochemical Ag deposition on FeNi‐mesh cathodes in Al‐air battery

Mutlu

Yazıcı

2018

Int J Energy Res

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Summary In this study, FeNi/Ag cathode was made for aluminium air battery. For this purpose, FeNi‐mesh electrode surfaces were treated in two different ways (chemical and electrochemical deposition), with noble metal silver having a high catalytic activity. The optimum time for both methods was determined. The electrochemical properties were determined using cyclic voltammogram (CV), electrochemical impedance spectroscopy (EIS), and current‐potential (i‐t) curves. The battery performance tests were performed, and surface characteristics of the electrodes were determined with a scanning electron microscope an X‐ray diffraction method (SEM‐EDS and XRD). This study shows that FeNi mesh electrodes chemically and electrochemically deposited with silver are alternative for oxygen‐reducing cathodes for aluminium air battery because they are cheap, practical, and effective. The electrochemical (FeNi/Ag‐ED) deposition is better than the chemical (FeNi/Ag‐CD) deposition in terms of both economical and higher battery potential.

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Electrocatalytic oxygen reduction on single-walled carbon nanotubes supported Pt alloys nanoparticles in acidic and alkaline conditions

Cited by 14 publications

References 44 publications

Nano-structured textiles as high-performance aqueous cathodes for microbial fuel cells

Nano-structured textiles as high-performance aqueous cathodes for microbial fuel cells

Spontaneous incorporation of gold in palladium-based ternary nanoparticles makes durable electrocatalysts for oxygen reduction reaction

The behavior of chemical and electrochemical Ag deposition on FeNi‐mesh cathodes in Al‐air battery

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