Synthesis of Iridium Nanocatalysts for Water Oxidation in Acid: Effect of the Surfactant

Arminio‐Ravelo, José Alejandro; Quinson, Jonathan; Pedersen, Mads A.; Kirkensgaard, Jacob J. K.; Arenz, Matthias; Escudero‐Escribano, María

doi:10.1002/cctc.201902190

“…With the development of new methods to test catalysts [58] and the demonstration of the toolbox approach with alternative precious metal catalyst like Ir [59] or Ru, [38] it is expected that this approach will be key to explore more complex materials like bimetallic catalysts, nanocomposites, [60] and more complex phenomenon like the joint effect of size and interparticle distance at the nanoscale, in order to develop more performant supported NP catalysts.…”

Section: Discussionmentioning

confidence: 99%

Beyond Active Site Design: A Surfactant‐Free Toolbox Approach for Optimized Supported Nanoparticle Catalysts

Quinson

¹

,

Kunz

²

,

Arenz

³

2021

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Developing new catalysts with superior activity, stability, and selectivity is the ultimate research goal in catalysis. However, a complete understanding of what makes new or already known supported catalysts performant is still challenging. In addition to a careful design of the catalytically active phase, properties such as the interparticle distance, the location of the active phase in the outer or inner pores of the support material, as well as preparation steps such as washing, storage conditions, and conditioning can severely affect the observed performance. With the example of supported Pt nanoparticles (NPs), it is illustrated how systematic studies, where only one experimental parameter is changed at a time independently of the others, provide detailed insights into supported heterogeneous catalyst design. To perform such studies, an integral toolbox approach based on a surfactant‐free colloidal synthesis of NPs is developed. This approach takes into account not only the design and production of the catalytically active phase but considers all steps prior to testing the catalyst. The toolbox is well suited to flag and address pitfalls beyond the active phase design, to study and optimize supported precious metal NPs for energy and chemical conversion processes.

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“…The main advantage of the surfactant-free synthesis as compared to other colloidal methods is that the supported catalysts can be used as prepared since the Ir NPs are not covered by stabilizing polymers such as polyvinylpyrrolidone (PVP). 15,17 However, our results clearly show that the catalysts prepared by the polyol synthesis suffer from a material loss during the flocculation and redispersion steps required to remove the solvent. Despite the same particle size as in the Co4Cat approach, the ECSA is significantly reduced.…”

Section: Discussionmentioning

confidence: 80%

“…[12][13][14] In particular, synthesis procedures avoiding the use of surfactants recently gained momentum since they lead to active catalysts. 15,16 One standard in this respect is the polyol process, mainly using alkaline ethylene glycol (EG) as combined solvent, reducing and colloidal stabilizer agent. 17 In a recent advancement of the colloidal approach, low boiling point solvents could be used as a replacement for EG, in a process we refer to as Co4Cat, leading to readily active catalysts.…”

Section: Introductionmentioning

confidence: 99%

Surfactant-Free Colloidal Strategies for Highly Dispersed and Active Supported IrO2 Catalysts: Synthesis and Performance Evaluation for the Oxygen Evolution Reaction

Bizzotto¹,

Quinson²,

Schröder³

et al. 2021

Preprint

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0

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Supported Ir oxide catalysts obtained from surfactant-free colloidal Ir nanoparticles (NPs) synthesized in alkaline methanol (MeOH), ethanol (EtOH), and ethylene glycol (EG) are investigated and compared. The comparison of independent techniques such as transition electron microscopy (TEM), small angle X-ray scattering (SAXS), and electrochemistry allows shedding light on the parameters that affect the dispersion of the active phase as well as the catalytic activity. The colloidal dispersions obtained are suitable to develop supported catalysts with little NP agglomeration on a carbon support leading to highly active catalysts with more than 400 A g-1Ir reached at 1.5 VRHE for the OER. While the more common surfactant-free alkaline EG synthesis requires flocculation and re-dispersion leading to Ir loss, the main difference between methanol and ethanol as solvent is related to the dispersibility of the support material. The choice of the suitable monoalcohol determines the maximum achieved Ir loading on the support without detrimental particle agglomeration. This simple consideration on catalyst design can readily lead to significantly improved catalysts.

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“…20 This phenomenon would also explain the relatively small ECSA values determined in previous work. 15 The MeOH-based catalysts are instead characterized by a substantially higher ECSA, i.e. 195…”

Section: Electrochemical and Electrocatalytic Characterizationmentioning

confidence: 99%

Surfactant-Free Colloidal Strategies for Highly Dispersed and Active Supported IrO2 Catalysts: Synthesis and Performance Evaluation for the Oxygen Evolution Reaction

Bizzotto¹,

Quinson²,

Schröder³

et al. 2021

Preprint

Self Cite

0

View full text Add to dashboard Cite

Supported Ir oxide catalysts obtained from surfactant-free colloidal Ir nanoparticles (NPs) synthesized in alkaline methanol (MeOH), ethanol (EtOH), and ethylene glycol (EG) are investigated and compared. The comparison of independent techniques such as transition electron microscopy (TEM), small angle X-ray scattering (SAXS), and electrochemistry allows shedding light on the parameters that affect the dispersion of the active phase as well as the catalytic activity. The colloidal dispersions obtained are suitable to develop supported catalysts with little NP agglomeration on a carbon support leading to highly active catalysts with more than 400 A g-1Ir reached at 1.5 VRHE for the OER. While the more common surfactant-free alkaline EG synthesis requires flocculation and re-dispersion leading to Ir loss, the main difference between methanol and ethanol as solvent is related to the dispersibility of the support material. The choice of the suitable monoalcohol determines the maximum achieved Ir loading on the support without detrimental particle agglomeration. This simple consideration on catalyst design can readily lead to significantly improved catalysts.

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Synthesis of Iridium Nanocatalysts for Water Oxidation in Acid: Effect of the Surfactant

Cited by 44 publications

References 48 publications

Beyond Active Site Design: A Surfactant‐Free Toolbox Approach for Optimized Supported Nanoparticle Catalysts

Beyond Active Site Design: A Surfactant‐Free Toolbox Approach for Optimized Supported Nanoparticle Catalysts

Surfactant-Free Colloidal Strategies for Highly Dispersed and Active Supported IrO2 Catalysts: Synthesis and Performance Evaluation for the Oxygen Evolution Reaction

Surfactant-Free Colloidal Strategies for Highly Dispersed and Active Supported IrO2 Catalysts: Synthesis and Performance Evaluation for the Oxygen Evolution Reaction

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