Platinum nanoparticles decorated carbon nanofiber hybrids as highly active electrocatalysts for polymer electrolyte membrane fuel cells

Kaplan, Begüm Yarar; Haghmoradi, Navid; Jamil, Esaam; Merino, C.; Gürsel, Selmiye Alkan

doi:10.1002/er.5646

Cited by 18 publications

(11 citation statements)

References 42 publications

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“…In previous studies in which the deposition method and/or the carbon‐based materials were different the resulted mass activities have been reported to be in the range of 0.063 to 0.272 A mg −1. 7,40 The charge transfer current coming from the kinetically controlled region, for the not‐modified sample, is higher than the modified one. This could be because of graphene's different structures coming from oxygen functional groups which were shown from XPS spectra of C 1s in Figures 6C,C.…”

Section: Resultsmentioning

confidence: 98%

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Pulsed‐UV illumination on graphene oxide: A new strategy in photocatalytic synthesis of electrocatalysts to control the structural and electrochemical properties

Haghmoradi

Sarı

Öztürk

et al. 2021

Intl J of Energy Research

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Summary This study demonstrated the capability of a novel method in controlling the structural and electrochemical properties of electrocatalysts, utilizing a pulsed‐ultraviolet (UV) setup for the synthesis procedure. A hand‐made reactor provided a new set of parameters. The variation of UVon and UVoff periods resulted in samples with a range of different structures, compositions, and activities. Graphene/Pt was prepared with varying forms of illumination pulse, and its hydrogen oxidation and oxygen reduction reaction performances were evaluated. Controlling the reduction degree of Pt ions on partially reduced graphene oxide was achieved by manipulating the setup design. The results revealed a dominant growth and agglomeration phase of Pt particles, mostly with metallic states, by increasing both UVon and Uoff time spontaneously. Long UVon without adequate UVoff did not result in promising electrocatalytic activities. In other words, different structures, compositions, and activities of samples suggested that not just the illumination is the crucial factor, it is also the resting time or UVoff which determines the surface adsorption kinetics, nucleation sites, and growth mechanism of nanoparticles. Further chemical reduction by highly concentrated ascorbic acid was used to confirm the proposed mechanisms, which lead to samples even with more metallic Pt (Pt0).

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Section: Resultsmentioning

confidence: 98%

“…Yet, the vulnerability of the conventional carbon black to harsh environments and corrosion increases the chance of detachment and agglomeration of Pt 6 . Consequently, a support material that could be highly stable and conductive is desirable 7 …”

Section: Introductionmentioning

confidence: 99%

Pulsed‐UV illumination on graphene oxide: A new strategy in photocatalytic synthesis of electrocatalysts to control the structural and electrochemical properties

Haghmoradi

Sarı

Öztürk

et al. 2021

Intl J of Energy Research

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“…The ECSA values obtained for the Pt/Ti_CPD_PED electrodes were six to ten times lower than the ECSA for state-of-the-art commercial Pt/C catalysts which range from 60 to 110 m echem. 2 g −1 [ 54 ]. Furthermore, compared to the 83.1 m echem.…”

Section: Resultsmentioning

confidence: 99%

“…2 g −1 to 80 m echem. 2 g −1 , the 2-PtIr electrode was outperformed [ 39 , 54 ]. Moreover, for nanocomposite PtIrO 2 /C catalysts prepared via chemical synthesis, ECSAs of 77 m echem.…”

Section: Resultsmentioning

confidence: 99%

Development of a Bifunctional Ti-Based Gas Diffusion Electrode for ORR and OER by One- and Two-Step Pt-Ir Electrodeposition

Cieluch¹,

Podleschny²,

Kazamer³

et al. 2022

Nanomaterials

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The present paper presents one- and two-step approaches for electrochemical Pt and Ir deposition on a porous Ti-substrate to obtain a bifunctional oxygen electrode. Surface pre-treatment of the fiber-based Ti-substrate with oxalic acid provides an alternative to plasma treatment for partially stripping TiO2 from the electrode surface and roughening the topography. Electrochemical catalyst deposition performed directly onto the pretreated Ti-substrates bypasses unnecessary preparation and processing of catalyst support structures. A single Pt constant potential deposition (CPD), directly followed by pulsed electrodeposition (PED), created nanosized noble agglomerates. Subsequently, Ir was deposited via PED onto the Pt sub-structure to obtain a successively deposited PtIr catalyst layer. For the co-deposition of PtIr, a binary PtIr-alloy electrolyte was used applying PED. Micrographically, areal micro- and nano-scaled Pt sub-structure were observed, supplemented by homogenously distributed, nanosized Ir agglomerates for the successive PtIr deposition. In contrast, the PtIr co-deposition led to spherical, nanosized PtIr agglomerates. The electrochemical ORR and OER activity showed increased hydrogen desorption peaks for the Pt-deposited substrate, as well as broadening and flattening of the hydrogen desorption peaks for PtIr deposited substrates. The anodic kinetic parameters for the prepared electrodes were found to be higher than those of a polished Ir-disc.

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“…[1][2][3] However, their high cost due to the exclusive use of expensive Pt and Pt-based catalysts 3,4 is still considered an obstacle to commercialization, despite the efforts to increase the mass activity of Pt. 5,6 As a promising alternative to PEMFCs, anion exchange membrane fuel cells (AEMFCs) have been receiving increasing attention mainly because they comprise non-precious metals and alloy catalysts in alkaline media with relatively high activity and stability. 7,8 Another benefit of using alkaline media, compared with acidic media, is the enhanced kinetics of the oxygen reduction reaction (ORR).…”

Section: Introductionmentioning

confidence: 99%

Electrodeposited NiRh alloy as an efficient low‐precious metal catalyst for alkaline hydrogen oxidation reaction

Tran

Park

Kim

et al. 2020

Intl J of Energy Research

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Developing a non-precious or low Pt-group metal-containing (low-PGM) hydrogen oxidation reaction (HOR) catalyst is crucial to fabricate economic anion exchange membrane fuel cells (AEMFCs), an alternative to proton exchange membrane fuel cells (PEMFC). In this study, low-PGM Ni 100-x Rh x electrocatalysts, seldomly studied as alkaline HOR catalysts, with various compositions are fabricated via electrodeposition. Substantial changes are observed in both the morphology and crystalline structure of the catalysts when Ni is alloyed with Rh, such as enlarged surface area and development of different textures. The HOR activities of Ni 100-x Rh x catalysts evaluated in 0.1 M KOH solution are dramatically enhanced because of the enlarged surface area, bifunctional roles of H-providing sites (Ni/Rh) and OH-providing sites (Ni [OH] 2 /Rh 2 O 3), and their balanced composition on the surface. The durability of Ni 89 Rh 11 , the most appropriate catalyst, is investigated with the 3000 potential cycling, giving the average decay rate of approximately 0.30 μA cm −2 /cycle. The origin of enhanced activity and degradation during durability test was explained in terms of the electronic structures and surface composition of the catalysts. The initial high HOR activity of about 1.5 mA/cm 2 for Ni 89 Rh 11 at 0.05 V RHE , though it requires a further improvement in the durability, suggests the practical feasibility of it as a low PGM alkaline HOR catalyst.

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Platinum nanoparticles decorated carbon nanofiber hybrids as highly active electrocatalysts for polymer electrolyte membrane fuel cells

Cited by 18 publications

References 42 publications

Pulsed‐UV illumination on graphene oxide: A new strategy in photocatalytic synthesis of electrocatalysts to control the structural and electrochemical properties

Pulsed‐UV illumination on graphene oxide: A new strategy in photocatalytic synthesis of electrocatalysts to control the structural and electrochemical properties

Development of a Bifunctional Ti-Based Gas Diffusion Electrode for ORR and OER by One- and Two-Step Pt-Ir Electrodeposition

Electrodeposited NiRh alloy as an efficient low‐precious metal catalyst for alkaline hydrogen oxidation reaction

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