Electrocatalysts Prepared by Galvanic Replacement

Papaderakis, Α.; Mintsouli, I.; Georgieva, J.; Sotiropoulos, S.

doi:10.3390/catal7030080

Cited by 114 publications

(69 citation statements)

References 303 publications

(394 reference statements)

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“…On‐the‐fly modification entails modification of catalyst metal surface by dopant(s) followed by the catalytic reaction that quantifies the effect of the modification. Nevertheless, we think methods such as atomic layer deposition (ALD), controlled surface reactions (CSR), and galvanic displacement can be easily adapted to performed similar on‐the‐fly modifications.…”

Section: Selective Surface Modificationmentioning

confidence: 99%

On‐the‐fly Catalyst Modification: Strategy to Improve Catalytic Processes Selectivity and Understanding

Sá

Medlin

2019

ChemCatChem

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Hydrogenation is a quintessential process to the chemical industry. It is heavily involved in organic synthesis and fuel production, among other processes. Preferentially the reactions are carried out with heterogeneous catalysts and when possible in flow mode. Herein, we provide a retrospective on selective surface modification of catalysts for improved selectivity and understanding of catalytic reactivity. In addition, we provide a prospectus for an emerging strategy of carrying out surface modification on-the-fly to produce novel catalysts in a fast and reproducible way and to understand catalytic phenomena.

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Section: Selective Surface Modificationmentioning

confidence: 99%

On‐the‐fly Catalyst Modification: Strategy to Improve Catalytic Processes Selectivity and Understanding

Sá

Medlin

2019

ChemCatChem

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“…[19] The successful replacement was confirmed and quantified by measuring the UV/Vis absorption of the released M 2 + speciesi nt he supernatant solutiona fter the Pd@M NPs synthesis ( Figure S1 in the Supporting Information). [19] The successful replacement was confirmed and quantified by measuring the UV/Vis absorption of the released M 2 + speciesi nt he supernatant solutiona fter the Pd@M NPs synthesis ( Figure S1 in the Supporting Information).…”

Section: Resultsmentioning

confidence: 89%

“…This is at hermodynamically favorable reactiona st he standard potentials of the Ni 2 + /Ni, Cu 2 + /Cu, and Co 2 + /Co couples are À0.257, À0.277, and + 0.340 V( vs. standard hydrogen electrode, SHE), respectively,l ower than that of PdCl 4 2À /Pd, being + 0.620 V( vs. SHE). [19] The successful replacement was confirmed and quantified by measuring the UV/Vis absorption of the released M 2 + speciesi nt he supernatant solutiona fter the Pd@M NPs synthesis ( Figure S1 in the Supporting Information). Based on these data, the Pd-to-M( M= Ni, Cu, Co) mass ratios were calculatedt ob e2 8:72, 30:70, and 29:71f or Pd@Ni NPs , Pd@Cu NPs ,a nd Pd@Co NPs ,r espectively,w hich are very close to the theoretically expected, asd esigned, value of 30:70.…”

Section: Resultsmentioning

confidence: 89%

Core–Shell Pd@M (M=Ni, Cu, Co) Nanoparticles/Graphene Ensembles with High Mass Electrocatalytic Activity Toward the Oxygen Reduction Reaction

Perivoliotis

Sato

Suenaga

et al. 2019

Chemistry A European J

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Herein, it is demonstrated that pyrene butyric acid (PBA)-stabilized metaln anoparticles with core-shell morphology, Pd@M NPs (M = Ni, Cu, Co), non-covalently supported on graphene (G) sheets, are more active towards oxygen electroreduction in alkaline environments than the benchmark Pd/C catalyst, albeit with a7 0% lower preciousm etal loading. The PBA-stabilized Pd@M NPs (M = Ni, Cu, Co)/G ensemblesw ere prepared by employing as imple modified polyol method andg alvanic replacementa nd thoroughly characterizedw ith advanced microscopy imaging and complementary spectroscopic techniques.E lectrochemical studies revealed that Pd@Ni NPs /G presents the optimump erformance, exhibiting a3 0mVm ore positive onset potential and 3.2 times greater mass activityo ver Pd/C. Moreover, chronoamperometric assays showedt he minimum activity loss for Pd@Ni NPs /G, not only among its core-shell counterparts buti mportantlyw hen compared with the benchmark catalyst.T he excellent performance of Pd@Ni NPs /G was attributed to the (a) presence of PBA as stabilizer,( b) uniform Pd@Ni NPs dispersion onto the graphene sheets, (c) efficient intra-ensemble interactions between the two species, (d) existence of the core-shell structure for Pd@Ni NPs ,a nd (e) stability of the Ni core metal under the reactionc onditions. Last, the oxygen reduction on Pd@Ni NPs /graphene occurs by the direct four-electron reduction pathway,s howinggreat potentialfor use in energy related applications.Supporting information and the ORCID identification number(s) for the author(s) of this article can be found under: https://doi.

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“…In particular, Pt extended surfaces deposited on high aspect-ratio materials such as nanofibers [19,21] and whiskers [22] presented exceptional increase of the ORR specific activity, which was kept after prolonged electrochemical cycling. Among the methods being investigated to produce Pt conformal thin films, atomic layer deposition (ALD), electrochemical atomic layer deposition (EC-ALD), pulsed laser deposition, surface-limited redox replacement (SLRR), galvanic displacement [18,[23][24][25] and other vacuum techniques, such as magnetron sputtering are employed [26].…”

Section: Introductionmentioning

confidence: 99%

Electrodeposition of two-dimensional Pt nanostructures on highly oriented pyrolytic graphite (HOPG): the effect of evolved hydrogen and chloride ions

Alpuche-Avilés

Farina

Ercolano

et al. 2018

Preprint

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We discuss the electrodeposition of two-dimensional (2D) Pt-nanostructures on HOPG achieved under constant applied potential versus a Pt counter electrode (Eappl = ca. - 2.2 V vs RHE). The deposition conditions are discussed in terms of the electrochemical behavior of the electrodeposition precursor (H2PtCl6). We performed cyclic voltammetry (CV) of the electrochemical Pt deposit on HOPG and on Pt substrates to study the relevant phenomena that affect the morphology of Pt deposition. Under conditions where the Pt deposition occurs and H2 evolution is occurring at the diffusion-limited rate (- 0.3 V vs RHE), Pt forms larger structures on the surface of HOPG, and the electrodeposition of Pt is not limited by diffusion. This indicates the need for large overpotentials to direct the 2D growth of Pt. Investigation of the possible effect of Cl- showed that Cl- deposits on the surface of Pt at low overpotentials, but strips from the surface at potentials more positive than the electrodeposition potential. The CV of Pt on HOPG is a strong function of the nature of the surface. We propose that during immersion of HOPG in the electrodeposition solution (3 mM H2PtCl6, 0.5 M NaCl, pH 2.3) Pt islands are formed spontaneously, and these islands drive the growth of the 2D nanostructures.

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Electrocatalysts Prepared by Galvanic Replacement

Cited by 114 publications

References 303 publications

On‐the‐fly Catalyst Modification: Strategy to Improve Catalytic Processes Selectivity and Understanding

On‐the‐fly Catalyst Modification: Strategy to Improve Catalytic Processes Selectivity and Understanding

Core–Shell Pd@M (M=Ni, Cu, Co) Nanoparticles/Graphene Ensembles with High Mass Electrocatalytic Activity Toward the Oxygen Reduction Reaction

Electrodeposition of two-dimensional Pt nanostructures on highly oriented pyrolytic graphite (HOPG): the effect of evolved hydrogen and chloride ions

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