Gold-in-copper at low *CO coverage enables efficient electromethanation of CO2

The renewable-electricity-powered CO2 electroreduction reaction provides a promising means to store intermittent renewable energy in the form of valuable chemicals and dispatchable fuels. Renewable methane produced using CO2 electroreduction attracts interest due to the established global distribution network; however, present-day efficiencies and activities remain below those required for practical application. Here we exploit the fact that the suppression of *CO dimerization and hydrogen evolution promotes methane selectivity: we reason that the introduction of Au in Cu favors *CO protonation vs. C-C coupling under low *CO coverage and weakens the *H adsorption energy of the surface, leading to a reduction in hydrogen evolution. We construct experimentally a suite of Au-Cu catalysts and control *CO availability by regulating CO2 concentration and reaction rate. This strategy leads to a 1.6x improvement in the methane:H-2 selectivity ratio compared to the best prior reports operating above 100mAcm(-2). We as a result achieve a CO2-to-methane Faradaic efficiency (FE) of (562)% at a production rate of (112 +/- 4) mA cm(-2). The electroreduction of CO2 offers a promising approach to produce carbon-neutral methane using renewable electricity. This study shows that the introduction of Au in Cu enables selective methane production from CO2 by regulating *CO availability.

Power-to-fuels via solid-oxide electrolyzer: Operating window and techno-economics

Stefan Diethelm, Tzu-En Lin, François Maréchal, Jan Van Herle, Ligang Wang

Power-to-fuel systems via solid-oxide electrolysis are promising for storing excess renewable electricity by efficient electrolysis of steam (or co-electrolysis of steam and CO2) into hydrogen (or syngas), which can be further converted into synthetic fuels with plant-wise thermal integration. Electrolysis stack performance and durability determine the system design, performance, and long-term operating strategy; thus, solid-oxide electrolyzer based power-to-fuels were investigated from the stack to system levels. At the stack level, the data from a 6000-h stack testing under laboratory isothermal conditions were used to calibrate a quasi-2D model, which enables to predict practical, isothermal stack performance with reasonable accuracy. Feasible stack operating windows meeting various design specifications (e.g., specific syngas composition) were further generated to support the selection of operating points. At the system level, with the chosen similar stack operating points, various power-to-fuel systems, including power-to-hydrogen, power-to-methane, power-to-methanol (dimethyl ether) and power-to-gasoline, were compared techno-economically considering system-level heat integration. Several operating strategies of the stack were compared to address the increase in stack temperature due to degradation. The modeling results show that the system efficiency for producing H2, methane, methanol/dimethyl ether and gasoline decreases sequentially from 94% (power-to-H2) to 64% (power-to-gasoline), based on a higher heating value. Co-electrolysis, which allows better heat integration, can improve the efficiency of the systems with less exothermic fuel-synthesis processes (e.g., methanol/dimethyl ether) but offers limited advantages for power-to-methane and power-to-gasoline systems. In a likely future scenario, where the growing amount of electricity from renewable sources results in increasing periods of a negative electricity price, solid oxide electrolyser based power-to-fuel sys

2019

Mesoscopic thin films of hematite as photoanode for water photoelectrolysis

Alexis Joseph Duret

Due to the limiting amount of fossil fuel available and to the continuous growth of the world energy consumption, it becomes important to find alternative energy sources. Hydrogen produced by the photoelectrolysis of water is a perfect candidate as a clean energy source since it can be produced and used efficiently without generating any pollution. The water oxidation to oxygen is a slow reaction that requires an important overpotential in order to reach a significant current. This problem is crucial in water photoelectrolysis: a high overpotential means more solar cells in series in order to obtain high enough conversion efficiency. In order to lower the number of solar cells in series, a photoactive anode can be used. One potentially good material for a photoanode is hematite: it is cheap, stable and it has a bandgap small enough to absorb a part of the visible light. The objective of the present work is to develop and characterize highly photoactive semi transparent thin films of hematite that could be used efficiently to photo oxidize water. Three different deposition methods have been tested: Spray Pyrolysis (SP), Ultrasonic Spray Pyrolysis (USP) and Electrostatic Spray Deposition (ESD). The films obtained were characterized using spectroscopic (UV-Vis absorption, SEM and Raman spectroscopy) and electrochemical techniques (current potential curves in dark and under light, IPCE spectra, photopotential measurements and electrochemical impedance spectroscopy). The films made by ESD were not photoactive. The films made by SP were weakly photoactive and the films made by USP gave the highest photocurrent. After an optimization step, films with a photocurrent of 0.5 and 1.07mA/cm-2 at 1200mV vs RHE and under 1.5AM were produced by SP and USP respectively. Ti[IV] doping improved the photoresponse of the films deposited by SP. An inverse effect was observed for the films deposited by USP: the introduction of a dopant lowered the photocurrent and increased the dark current. The properties of layers made by USP were compared to those deposited by SP. Although both types of films show similar XRD, UV-visible and Raman spectra they differ greatly in their morphology and in their photoactivity. The mesoscopic α-Fe2O3 layers produced by USP consist mainly of 100 nm- sized platelets with a thickness of 5-10 nanometers. These nanosheets are oriented perpendicularly to the FTO support, their flat surface exposing (001) facets. The films made by SP consist of spherical hematite particles of 50-100nm in diameter densely packed. Open circuit photovoltage measurements indicated a lower surface state density for the films made by USP as compared to the films made by SP. This factor explained the much higher photoactivity of the USP compared to the SP deposited α-Fe2O3 films. Addition of hydrogen peroxide to the alkaline electrolyte further improves the photocurrent-voltage characteristics of films generated by USP and SP indicating hole transfer from the valence band of the semiconductor oxide to the adsorbed water to be the rate limiting kinetic step in the oxygen generation reaction. Electrochemical impedance spectroscopy (EIS) experiments have been performed on the most photoactive USP films. The construction of a frequency independent Mott-Schottky plot showed that the hematite flat band potential lies at 0.26V vs RHE in 1M NaOH and that the donor concentration is 5.6 1017cm-3. EIS allowed the identification of a deep donor level 0.3V above the flat band potential. This level explains the difference between the onset potential and the flat band potential. The electrochemical and photoelectrochemical behaviors of the most photoactive hematite thin films deposited by USP were found to be really close to those of single crystal hematite indicating that the influence on the photoactivity of the grain boundaries can be neglected.

EPFL2005

Mesoscopic thin films of hematite as photoanode for water photoelectrolysis

Alexis Joseph Duret

EPFL2005

Power-to-fuels via solid-oxide electrolyzer: Operating window and techno-economics

Stefan Diethelm, Tzu-En Lin, François Maréchal, Jan Van Herle, Ligang Wang

2019