Probing the Dynamics of Low-Overpotential CO<sub>2</sub>-to-CO Activation on Copper Electrodes with Time-Resolved Raman Spectroscopy

Ruiter, Jim de; An, Hongyu; Wu, Longfei; Gijsberg, Zamorano; Yang, Shuang; Hartman, Thomas; Weckhuysen, Bert M.; Stam, Ward van der

doi:10.1021/jacs.2c03172

Cited by 55 publications

(77 citation statements)

References 70 publications

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“…Scans were acquired from 1.0 V versus RHE to −0.95 V versus RHE under in situ conditions. As shown in Figure c, a similar change in the electrocatalyst structure is found for the pristine CuO nanoparticles during the cathodic scan from 1.0 to −0.95 V versus RHE: Initially, CuO is reduced to Cu 2 O, followed by Cu 2 O reduction to metallic Cu . Reduction to metallic Cu is directly followed by the appearance of the band associated with Cu–C at 360 cm –1 , evidencing the presence of *CO as confirmed by the spectra in the CO region (Figure d, around 2000 cm –1 ).…”

Section: Resultssupporting

confidence: 73%

Near-Unity Electrochemical CO₂ to CO Conversion over Sn-Doped Copper Oxide Nanoparticles

Yang

Liu

et al. 2022

ACS Catal.

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Bimetallic electrocatalysts have emerged as a viable strategy to tune the electrocatalytic CO2 reduction reaction (eCO2RR) for the selective production of valuable base chemicals and fuels. However, obtaining high product selectivity and catalyst stability remain challenging, which hinders the practical application of eCO2RR. In this work, it was found that a small doping concentration of tin (Sn) in copper oxide (CuO) has profound influence on the catalytic performance, boosting the Faradaic efficiency (FE) up to 98% for carbon monoxide (CO) at −0.75 V versus RHE, with prolonged stable performance (FE > 90%) for up to 15 h. Through a combination of ex situ and in situ characterization techniques, the in situ activation and reaction mechanism of the electrocatalyst at work was elucidated. In situ Raman spectroscopy measurements revealed that the binding energy of the crucial adsorbed *CO intermediate was lowered through Sn doping, thereby favoring gaseous CO desorption. This observation was confirmed by density functional theory, which further indicated that hydrogen adsorption and subsequent hydrogen evolution were hampered on the Sn-doped electrocatalysts, resulting in boosted CO formation. It was found that the pristine electrocatalysts consisted of CuO nanoparticles decorated with SnO2 domains, as characterized by ex situ high-resolution scanning transmission electron microscopy and X-ray photoelectron spectroscopy measurements. These pristine nanoparticles were subsequently in situ converted into a catalytically active bimetallic Sn-doped Cu phase. Our work sheds light on the intimate relationship between the bimetallic structure and catalytic behavior, resulting in stable and selective oxide-derived Sn-doped Cu electrocatalysts.

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Section: Resultssupporting

confidence: 73%

Near-Unity Electrochemical CO₂ to CO Conversion over Sn-Doped Copper Oxide Nanoparticles

Yang

Liu

et al. 2022

ACS Catal.

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“…Meanwhile, positions of the CO L band under 20 and 40 barg of CO almost overlap at all potentials, suggesting similar absolute CO coverages. We note that the CO L band can consist of the low frequency band (LFB) (∼2073 cm –1 ) and high frequency band (HFB) (∼2093 cm –1 ) attributed to the CO adsorbed on terrace and undercoordinated sites, respectively. − Our spectra show that the CO L band mainly consists of LFB, indicating a major CO L population on terrace sites.…”

Section: Resultsmentioning

confidence: 72%

Correlating CO Coverage and CO Electroreduction on Cu via High-Pressure in Situ Spectroscopic and Reactivity Investigations

Hou

Chang

et al. 2022

J. Am. Chem. Soc.

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The absolute coverage of CO has been a missing piece in the mechanistic puzzle of the CO reduction reaction (CORR) on Cu. For the first time, we revealed the upper bound of the CO coverage under electrocatalytic conditions to be 0.05 monolayer at atmospheric pressure and the saturation CO coverage to be ∼0.25 monolayer by conducting surface enhanced infrared spectroscopy at CO pressures up to 60 barg in a custom-designed spectroelectrochemical cell. CORR activities on Cu were also determined in the same pressure range. Calculated reaction orders of C 2+ products with respect to adsorbed CO are substantially less than unity, clearly indicating that the coupling of adsorbed CO is not the rate-determining step leading to multicarbon products. The increase in CO coverage can reduce the C affinity on the Cu surface and favor the selectivity towards oxygenates, especially acetate, over ethylene. Uncommon products, including ethane, glycolaldehyde, and ethylene glycol, were detected in appreciable amounts, likely due to a new C−C coupling mechanism taking place at elevated CO pressures.

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“…Although special cell designs are necessary for the proper use of infrared spectroscopy, which relies on ATR crystals, Raman spectroscopy and X-ray spectroscopy and diffraction can be readily applied. Raman spectroscopy is of particular interest in our research endeavors, because it allows to probe the catalyst structure (<700 cm –1 Raman shift) and electrolyte species (1000–1500 cm –1 ) as well as key reaction intermediates (>2000 cm –1 ) simultaneously . However, due to the low Raman scattering probability, the signal intensity is relatively low, which hampers the time and space resolution.…”

Section: In Situ Multiscale Characterization Of (De)activation Of Ele...mentioning

confidence: 99%

“…Every technique has its pros and cons in terms of time and space resolution but also sensitivity and reaction conditions. For example, Raman spectroscopy is frequently applied to study the adsorbed intermediates at the electrocatalyst surface but relies heavily on signal enhancement through the surface enhanced Raman spectroscopy (SERS) effect. , Therefore, special care needs to be taken to ensure that the SERS effect is homogeneous and that the probed surface is representative for the catalytic activity. This can only be achieved through the use of complementary techniques or through an internal standard in the Raman spectra (e.g., a vibration of an electrolyte species that does not change over time).…”

Section: Prospects For Technique Development and Combined Characteriz...mentioning

confidence: 99%

“…For example, Raman spectroscopy is often performed in a microscope, which poses limitations for the characterization of GDEs and MEAs. In our current setup, we utilize a water immersion objective to boost the signal-to-noise ratio and measure selectively at the electrode/electrolyte interface. , In a GDE configuration, it should be possible to apply Raman spectroscopy and measure the electrode/electrolyte interface in a similar fashion with a water immersion objective, but the in situ Raman cell needs to be carefully designed to ensure optimal electrocatalytic performance (high current densities). Potentially, Raman spectroscopy should be performed in transmission mode for in situ GDE characterization, for which high intensity laser setups should be developed without the need for objectives.…”

Section: In Situ Characterization Under Industrial Conditionsmentioning

confidence: 99%

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The Necessity for Multiscale In Situ Characterization of Tailored Electrocatalyst Nanoparticle Stability

Stam

2023

Chem. Mater.

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Tailored nanoparticles have opened up several exciting avenues to boost the activity and selectivity of structure-sensitive electrocatalytic reactions, such as the electrochemical carbon dioxide (CO2) reduction (eCO2RR). Colloidal chemistry provides the perfect toolbox to synthesize electrocatalyst nanoparticles on demand with atomic precision, in order to control and steer the electrocatalytic reactions of interest to the desired products. Not only does colloidal chemistry offer a means to prepare nanoparticles with well-defined sizes and shapes, it also allows easy deposition on any desired substrate (e.g., porous substrates) due to the solution processability. But what you see after synthesis with ex situ characterization techniques is not always what you get during the electrocatalytic reaction. Like any other electrocatalyst material, colloidal nanoparticles are prone to restructuring, and hence, the reaction output is altered due to destabilization of the electrocatalyst. This destabilization of the electrocatalyst nanoparticles is currently one of the major bottlenecks for the widespread implementation of electrocatalysts in the chemical industry. This calls for the necessary development and application of in situ characterization techniques to probe the morphology and composition of the tailored electrocatalyst nanoparticles over multiple length scales, in order to rationally design the next generation of stable electrocatalyst nanoparticles. Through detailed spatiotemporal in situ characterization, we can take full advantage of the possibilities that colloidal chemistry offers for electrocatalyst preparation with superior activity, selectivity, and stability. In this perspective, the necessity for in situ characterization of electrocatalyst nanoparticle stability is highlighted. For this purpose, first the progress of colloidal nanoparticles for electrocatalytic conversion reactions is briefly discussed, after which the focus shifts toward in situ characterization of the (in)stability of the tailored nanoparticles during the reaction of interest, ideally under industrially relevant conditions. This perspective shows that in situ characterization of electrocatalyst deactivation requires a multiscale approach, and that without combined in situ characterization we will remain blind to several aspects that are known to influence electrocatalyst performance.

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Probing the Dynamics of Low-Overpotential CO₂-to-CO Activation on Copper Electrodes with Time-Resolved Raman Spectroscopy

Cited by 55 publications

References 70 publications

Near-Unity Electrochemical CO₂ to CO Conversion over Sn-Doped Copper Oxide Nanoparticles

Near-Unity Electrochemical CO₂ to CO Conversion over Sn-Doped Copper Oxide Nanoparticles

Correlating CO Coverage and CO Electroreduction on Cu via High-Pressure in Situ Spectroscopic and Reactivity Investigations

The Necessity for Multiscale In Situ Characterization of Tailored Electrocatalyst Nanoparticle Stability

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Probing the Dynamics of Low-Overpotential CO2-to-CO Activation on Copper Electrodes with Time-Resolved Raman Spectroscopy

Cited by 55 publications

References 70 publications

Near-Unity Electrochemical CO2 to CO Conversion over Sn-Doped Copper Oxide Nanoparticles

Near-Unity Electrochemical CO2 to CO Conversion over Sn-Doped Copper Oxide Nanoparticles

Correlating CO Coverage and CO Electroreduction on Cu via High-Pressure in Situ Spectroscopic and Reactivity Investigations

The Necessity for Multiscale In Situ Characterization of Tailored Electrocatalyst Nanoparticle Stability

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Probing the Dynamics of Low-Overpotential CO₂-to-CO Activation on Copper Electrodes with Time-Resolved Raman Spectroscopy

Near-Unity Electrochemical CO₂ to CO Conversion over Sn-Doped Copper Oxide Nanoparticles

Near-Unity Electrochemical CO₂ to CO Conversion over Sn-Doped Copper Oxide Nanoparticles