Takumi Okuyama scite author profile

Exchanged: The organic radical 2‐azaadamantan‐N‐oxyl (AZA; see picture) is found to be a stable and highly reactive redox mediator in dye‐sensitized solar cell (DSSC) electrolytes. This radical has an appropriate redox potential and significantly high values for the diffusivity, heterogeneous electron‐transfer rate, and electron self‐exchange reaction rate. In a DSSC the AZA‐based electrolyte achieves an excellent photovoltaic performance.

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Nitroxide Radicals as Highly Reactive Redox Mediators in Dye‐Sensitized Solar Cells

Kato

Kikuchi

Okuyama

et al. 2012

Angewandte Chemie

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Ausgetauscht: Das 2‐Azaadamantan‐N‐oxyl‐Radikal (siehe Bild) erweist sich als stabiler und hochreaktiver Redoxmediator in Farbstoffsolarzellen‐Elektrolyten. Das Radikal hat ein geeignetes Redoxpotential und zeigt signifikant hohe Diffusionsgeschwindigkeitskonstanten sowie heterogene Elektronentransfer‐ und Elektronenaustauschgeschwindigkeiten. Mit dem Elektrolyt werden exzellente photovoltaische Leistungen erzielt.

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Study of Ionomer Adsorption on Carbon Supported Pt Catalyst By the Quartz-Crystal Microbalance (QCM) Method

2015

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In polymer electrolyte fuel cells, the three-phase interface in a catalyst layer (CL) is considered to be very important as the electrochemical reaction site. The CL is typically formed using a dispersion of carbon supported platinum catalyst (Pt/C) and ionomer, and the interaction between the ionomer and Pt/C particles probably has an impact on the platinum utilization in the electrode and the dispersion stability. In this study, we focused on the adsorptive property of ionomers onto the Pt/C surface. The amount of adsorbed ionomer on a Pt/C catalyst was measured using the quartz-crystal microbalance (QCM) method. The amount was used as an index of the affinity of the ionomer for the Pt/C catalyst surface. The Pt/C catalyst particles were immobilized on a QCM sensor. The catalyst-immobilized sensor was placed into a solvent, and was left for a while until the QCM oscillation stabilized. An ionomer solution was then added drop-wise into the QCM cell. The change in resonance frequency of the quatz-crystal before and after adding the ionomer dispersion was recorded. The amount of a perfluorosulfonic acid polymer, Flemion® (Asahi Glass), adsorbed on the Pt/C catalyst surface is plotted against the concentration of the ionomer dispersion in Fig.. The amount was calculated based on the change in the resonance frequency of the QCM sensor. It shows the higher the ionomer concentration, the more ionomer was adsorbed. The relationship between the adsorptive property of various ionomers will be discussed in terms of their chemical properties (IEC, chemical structure etc.). The viscoelastic character of the adsorbed ionomer layers will also be described. Figure 1

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Takumi Okuyama

Nitroxide Radicals as Highly Reactive Redox Mediators in Dye‐Sensitized Solar Cells

Nitroxide Radicals as Highly Reactive Redox Mediators in Dye‐Sensitized Solar Cells

Study of Ionomer Adsorption on Carbon Supported Pt Catalyst By the Quartz-Crystal Microbalance (QCM) Method

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