A Discussion on the Unique Features of Electrochemical Promotion of Catalysis (EPOC): Are We in the Right Path Towards Commercial Implementation?

Abstract: The phenomenon of “Non-Faradaic Electrochemical Modification of Catalytic Activity (NEMCA)” or “Electrochemical Promotion of Catalysis (EPOC)” has been extensively studied for the last decades. Its main strength, with respect to conventionally promoted catalytic systems, is its capability to modify in-situ the activity and/or selectivity of a catalyst by controlling the supply and removal of promoters upon electrical polarization. Previous reviews have summarized the main achievements in this field from both t… Show more

“…21,33,[35][36][37] In contrast to the traditionally used organometallic pastes, the main advantage of free-standing NPs includes the uniform metal dispersion on the solid electrolyte as well as thin and highly porous catalytic films. 26 In this regard, the used sample was characterized through scanning electron microscopy (SEM). Fig.…”

“…21 More specifically, the EPOC effect, also known as non-faradaic electrochemical modification of catalytic activity (NEMCA) is a highly utilized tool in heterogeneous catalysis over the past 40 years. [22][23][24][25][26][27] This effect is commonly studied with a simple and straightforward experimental set up involving three metal electrodes deposited onto a solid electrolyte/ion conductor as shown in Fig. S1.…”

Electrochemical control of the RWGS reaction over Ni nanoparticles deposited on yttria stabilized zirconia

“…21,33,[35][36][37] In contrast to the traditionally used organometallic pastes, the main advantage of free-standing NPs includes the uniform metal dispersion on the solid electrolyte as well as thin and highly porous catalytic films. 26 In this regard, the used sample was characterized through scanning electron microscopy (SEM). Fig.…”

“…21 More specifically, the EPOC effect, also known as non-faradaic electrochemical modification of catalytic activity (NEMCA) is a highly utilized tool in heterogeneous catalysis over the past 40 years. [22][23][24][25][26][27] This effect is commonly studied with a simple and straightforward experimental set up involving three metal electrodes deposited onto a solid electrolyte/ion conductor as shown in Fig. S1.…”

Electrochemical control of the RWGS reaction over Ni nanoparticles deposited on yttria stabilized zirconia

“…SR of methanol can be the most relevant case to ethanol reforming as both feedstocks categorized as primary alcohols, and the studied catalytic systems were Ni and Cu both supported on KβAl2O3 [38,39]. Most of these studies have shown the interest of EPOC in the H2 production technology 4 as reviewed in recent publications [44,45]. Nonetheless, the commercial implantation of the EPOC phenomenon has not been developed yet, being the poorly dispersed materials on the electrode, the reactor configuration or the study of the adequate processes the main drawbacks [45].…”

“…Most of these studies have shown the interest of EPOC in the H2 production technology 4 as reviewed in recent publications [44,45]. Nonetheless, the commercial implantation of the EPOC phenomenon has not been developed yet, being the poorly dispersed materials on the electrode, the reactor configuration or the study of the adequate processes the main drawbacks [45].…”

Electrochemical promotion of ethanol partial oxidation and reforming reactions for hydrogen production

“…9,12,13 This process has been shown to increase the EO selectivity with relatively small (μA/cm 2 to mA/cm 2 ) applied currents. 3,14,15 Previous studies have examined the effect of varying current density on selectivity at different applied currents and demonstrate that a higher applied current increases selectivity and total catalytic rate. 16 The proper molar ratio of ethylene to oxygen in the feed gas is not well agreed upon, with studies finding evidence that both ethylene-rich and oxygen-rich feeds produce a higher selectivity.…”

Short Term Silver Electrode Microstructure Changes Under Epoxidation Conditions for Solid Oxide Electrolysis Cells