Sandra Krick Calderón scite author profile

The carbon–carbon coupling via electrochemical reduction of carbon dioxide represents the biggest challenge for using this route as platform for chemicals synthesis. Here we show that nanostructured iron (III) oxyhydroxide on nitrogen-doped carbon enables high Faraday efficiency (97.4%) and selectivity to acetic acid (61%) at very-low potential (−0.5 V vs silver/silver chloride). Using a combination of electron microscopy, operando X-ray spectroscopy techniques and density functional theory simulations, we correlate the activity to acetic acid at this potential to the formation of nitrogen-coordinated iron (II) sites as single atoms or polyatomic species at the interface between iron oxyhydroxide and the nitrogen-doped carbon. The evolution of hydrogen is correlated to the formation of metallic iron and observed as dominant reaction path over iron oxyhydroxide on oxygen-doped carbon in the overall range of negative potential investigated, whereas over iron oxyhydroxide on nitrogen-doped carbon it becomes important only at more negative potentials.

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Interfaces of ionic liquids and transition metal surfaces—adsorption, growth, and thermal reactions of ultrathin [C1C1Im][Tf2N] films on metallic and oxidised Ni(111) surfaces

Cremer

Wibmer

Calderón

et al. 2012

Phys. Chem. Chem. Phys.

177

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Ultrathin films of the ionic liquid 1,3-dimethylimidazolium bis(trifluoromethylsulfonyl)imide ([C(1)C(1)Im][Tf(2)N]) were deposited on differently terminated Ni(111) single crystal surfaces. The initial wetting behaviour, the growth characteristics, the molecular arrangement at the interface, and thermal reactivity were investigated using angle-resolved X-ray photoelectron spectroscopy (ARXPS). On clean Ni(111), the initial growth occurs in a layer-by-layer mode. At submonolayer coverages up to at least 0.40 ML, a preferential arrangement of the IL ions in a bilayer structure, with the imidazolium cations in contact with the Ni surface atoms and the anions on top of the cation, is deduced. For higher coverages, a transition to a checkerboard-type arrangement occurs, which is most likely due to repulsive dipole-dipole interactions in the first layer. An overall preference for a checkerboard-type adsorption behaviour, i.e., anions and cations adsorbing next to each other, is found on the oxygen-precovered O(√3×√3)R30° Ni(111) surface. The thermal stability of adsorbed IL layers on Ni(111) and on a fully oxidised Ni(111) surface was studied by heating the layers to elevated temperatures. For clean Ni(111) reversible adsorption takes place. For the oxidised surface, however, only cation-related moieties desorb, starting at ~450 K, while anion-related signals remain on the surface up to much higher temperatures.

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The Synthesis of Nanostructured Ni₅P₄ Films and their Use as a Non‐Noble Bifunctional Electrocatalyst for Full Water Splitting

et al. 2015

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The investigation of nickel phosphide (Ni 5 P 4 )a s ac atalyst for the hydrogen (HER) and oxygen evolution reaction (OER) in strong acidic and alkaline environment is described. The catalyst can be grown in a3 Dh ierarchical structure directly on anickel substrate,thus making it an ideal candidate for practical water splitting devices.T he activity of the catalyst towards the HER, together with its high stability especially in acidic solution, makes it one of the best non-noble materials described to date.F urthermore,N i 5 P 4 was investigated in the OER and showed activity superior to pristine nickel or platinum. The practical relevance of Ni 5 P 4 as ab ifunctional catalyst for the overall water splitting reaction was demonstrated, with 10 mA cm À2 achieved below1 .7 V.The availability of peak excess electricity from wind and solar energy makes temporal storage in high-energy chemicals am andatory task for chemistry.H ere,t he focus lies especially on hydrogen which can be "easily" electrolyzed from water, then effectively reconverted into electricity with an umber of available devices. [1] Although electrolysis of water into hydrogen and oxygen is considered to be one of the easiest and cleanest methods to obtain hydrogen, this reaction is far from optimized. Currently,t he reaction still requires high overpotentials for both the hydrogen (HER) and oxygen evolution reaction (OER) to obtain decent reaction rates.For example,a round 50 %( 1.8-2 Vi nstead of 1.23 V) excess potential is required in industrial electrolyzer cells,w hich account for less than 5% of the world production of hydrogen. [2] This excess potential already represents an energy penalty of at least 35 %i nt he first conversion step, which makes it less attractive for an energy storage scheme.In addition, common electrolyzers are based on rare noble metals,s uch as Pt alloys for hydrogen evolution and IrO 2 / RuO 2 for oxygen evolution, and ab roader distribution of such devices stays rather questionable.

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Carbon Dioxide Capture by an Amine Functionalized Ionic Liquid: Fundamental Differences of Surface and Bulk Behavior

et al. 2013

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Carbon dioxide (CO2) absorption by the amine-functionalized ionic liquid (IL) dihydroxyethyldimethylammonium taurinate at 310 K was studied using surface- and bulk-sensitive experimental techniques. From near-ambient pressure X-ray photoelectron spectroscopy at 0.9 mbar CO2, the amount of captured CO2 per mole of IL in the near-surface region is quantified to ~0.58 mol, with ~0.15 mol in form of carbamate dianions and ~0.43 mol in form of carbamic acid. From isothermal uptake experiments combined with infrared spectroscopy, CO2 is found to be bound in the bulk as carbamate (with nominally 0.5 mol of CO2 bound per 1 mol of IL) up to ~2.5 bar CO2, and as carbamic acid (with nominally 1 mol CO2 bound per 1 mol IL) at higher pressures. We attribute the fact that at low pressures carbamic acid is the dominating species in the near-surface region, while only carbamate is formed in the bulk, to differences in solvation in the outermost IL layers as compared to the bulk situation.

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