The durability of electrode materials is a limiting parameter for many electrochemical energy conversion systems. In particular, electrocatalysts for the essential oxygen reduction reaction (ORR) present some of the most challenging instability issues shortening their practical lifetime. Here, we report a mesostructured graphitic carbon support, Hollow Graphitic Spheres (HGS) with a specific surface area exceeding 1000 m(2) g(-1) and precisely controlled pore structure, that was specifically developed to overcome the long-term catalyst degradation, while still sustaining high activity. The synthetic pathway leads to platinum nanoparticles of approximately 3 to 4 nm size encapsulated in the HGS pore structure that are stable at 850 °C and, more importantly, during simulated accelerated electrochemical aging. Moreover, the high stability of the cathode electrocatalyst is also retained in a fully assembled polymer electrolyte membrane fuel cell (PEMFC). Identical location scanning and scanning transmission electron microscopy (IL-SEM and IL-STEM) conclusively proved that during electrochemical cycling the encapsulation significantly suppresses detachment and agglomeration of Pt nanoparticles, two of the major degradation mechanisms in fuel cell catalysts of this particle size. Thus, beyond providing an improved electrocatalyst, this study describes the blueprint for targeted improvement of fuel cell catalysts by design of the carbon support.
The growing societal and political focus on the use of environmentally
friendly technologies has led to an ever-increasing interest in electrolysis
technologies in the scientific communities. This development is reflected
by the plethora of candidate catalysts for the hydrogen and oxygen
evolution reactions, as well as the CO
2
reduction reaction,
reported in the literature. However, almost none of them entered the
stage of application yet. Likewise, the reports on process engineering
inadequately address the utilization of these catalysts, as well as
electrode and cell concepts, that might be suitable for the market.
Evidently, a closer collaboration between chemists and engineers from
industry and academia is desirable to speed up the development of
these disruptive technologies. Herein, we elucidate the critical parameters
and highlight the necessary aspects to accelerate the development
of industrially relevant catalysts capable of fulfilling the forthcoming
challenges related to energy conversion and storage. The aim of this
Perspective, composed by industrial and academic partners, is to critically
question current undertakings and to encourage researchers to strike
interdisciplinary research pathways.
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