Your search keyword '"Glezakou, Vassiliki-Alexandra"' showing total 5 results

1. Hydrogen Bonding Enhances the Electrochemical Hydrogenation of Benzaldehyde in the Aqueous Phase.

Author

Sanyal, Udishnu, Yuk, Simuck F., Koh, Katherine, Lee, Mal‐Soon, Stoerzinger, Kelsey, Zhang, Difan, Meyer, Laura C., Lopez‐Ruiz, Juan A., Karkamkar, Abhi, Holladay, Jamie D., Camaioni, Donald M., Nguyen, Manh‐Thuong, Glezakou, Vassiliki‐Alexandra, Rousseau, Roger, Gutiérrez, Oliver Y., and Lercher, Johannes A.

Subjects

HYDROGEN bonding, HYDROGENATION, BENZYL alcohol, OXONIUM ions, CARBONYL group, BENZALDEHYDE, ADSORBATES

Abstract

The hydrogenation of benzaldehyde to benzyl alcohol on carbon‐supported metals in water, enabled by an external potential, is markedly promoted by polarization of the functional groups. The presence of polar co‐adsorbates, such as substituted phenols, enhances the hydrogenation rate of the aldehyde by two effects, that is, polarizing the carbonyl group and increasing the probability of forming a transition state for H addition. These two effects enable a hydrogenation route, in which phenol acts as a conduit for proton addition, with a higher rate than the direct proton transfer from hydronium ions. The fast hydrogenation enabled by the presence of phenol and applied potential overcompensates for the decrease in coverage of benzaldehyde caused by competitive adsorption. A higher acid strength of the co‐adsorbate increases the intensity of interactions and the rates of selective carbonyl reduction. [ABSTRACT FROM AUTHOR]

Published

2021

2. Electrochemically Tunable Proton‐Coupled Electron Transfer in Pd‐Catalyzed Benzaldehyde Hydrogenation.

Author

Koh, Katherine, Sanyal, Udishnu, Lee, Mal‐Soon, Cheng, Guanhua, Song, Miao, Glezakou, Vassiliki‐Alexandra, Liu, Yue, Li, Dongsheng, Rousseau, Roger, Gutiérrez, Oliver Y., Karkamkar, Abhijeet, Derewinski, Miroslaw, and Lercher, Johannes A.

Subjects

BENZALDEHYDE, BENZYL alcohol, OXONIUM ions, HYDROGENATION, METAL ions

Abstract

Acid functionalization of a carbon support allows to enhance the electrocatalytic activity of Pd to hydrogenate benzaldehyde to benzyl alcohol proportional to the concentration of Brønsted‐acid sites. In contrast, the hydrogenation rate is not affected when H2 is used as a reduction equivalent. The different responses to the catalyst properties are shown to be caused by differences in the hydrogenation mechanism between the electrochemical and the H2‐induced hydrogenation pathways. The enhancement of electrocatalytic reduction is realized by the participation of support‐generated hydronium ions in the proximity of the metal particles. [ABSTRACT FROM AUTHOR]

Published

2020

3. Impact of functional groups on the electrocatalytic hydrogenation of aromatic carbonyls to alcohols.

Author

Akhade, Sneha A., Lee, Mal-Soon, Meyer, Laura C., Yuk, Simuck F., Nguyen, Manh-Thuong, Sanyal, Udishnu, Egbert, Jonathan D., Gutiérrez, Oliver Y., Glezakou, Vassiliki-Alexandra, and Rousseau, Roger

Subjects

*FUNCTIONAL groups, *MOLECULAR structure, *CARBONYL group, *HYDROGENATION, *MOLECULAR dynamics, *ANGIOTENSIN I, *BENZALDEHYDE

Abstract

Electrocatalytic hydrogenation (ECH) of biomass-derived feedstocks has a critical dependence on the molecular structure of the organic and its adsorption on the electrode surface. In this study, we investigated the role of functional groups in the adsorption of the organic molecule on the charged Pd (111) surface and its subsequent effect on organic reduction in electrochemical hydrogenation of organic molecules. With three aromatic carbonyls of benzaldehyde (BZD), acetophenone (ACE), and vanillin (VAN), we rationalize molecular-scale adsorption and interfacial charge transfer processes by employing density-functional-theory based ab initio molecular dynamics simulations. We observe that the functional group and electrode charge strongly affect the proximity of organic molecule to the Pd (111) surface, where distances of aromatic ring and carbonyl group of the organic on the electrode change distinctively with functional groups and charge state of electrode, which strongly impact reduction of organics on the surface. Calculations of differential electron density show the strongest reduction with benzaldehyde via interfacial electron transfer from the charged Pd surface. We also observe that the interaction between the functional groups and solvent (VAN > BZD > ACE) significantly influence the organic interaction with the charged electrode (BZD > VAN > ACE), resulting in the net interaction energy between the organic and the electrode in the order of BZD > ACE > VAN. Experimental measurement of ECH rate also show the same trend of the net interaction energy. These results demonstrate the significance of solvent effect on the reducibility of organic molecules on electrodes. [Display omitted] • The organic functional group has a large impact on ECH with metal electrode. • The organic functional group influences structure and binding on metal surface. • Solvent also impacts the organic-electrode interaction energy. • The organic having the lowest reduction potential shows the highest ECH rate. [ABSTRACT FROM AUTHOR]

Published

2022

4. First-principle investigation on catalytic hydrogenation of benzaldehyde over Pt-group metals.

Author

Yuk, Simuck F., Lee, Mal-Soon, Akhade, Sneha A., Nguyen, Manh-Thuong, Glezakou, Vassiliki-Alexandra, and Rousseau, Roger

Subjects

*BENZALDEHYDE, *ACTIVATION energy, *SURFACE charges, *CARBON offsetting, *DENSITY functional theory, *CATALYTIC hydrogenation, *PLATINUM group

Abstract

[Display omitted] • A site preference for H 2 adsorption is different between Pt and Pd surfaces. • The site competition between H and benzaldehyde is seen on Pt unlike Pd surface. • The benzaldehyde is strongly adsorbed and hence reduced on the charged Pd surface. • The presence of H 2 O solvent and surface charge impacts hydrogenation on Pd(111). Understanding the hydrogenation of organic compounds in the aqueous phase has always been fundamentally important for improving carbon neutral pathways to fuels and value-added chemicals. In this study, we investigated both thermodynamic and kinetic profiles of benzaldehyde hydrogenation over the Pd(111) and Pt(111) metal surfaces using density functional theory (DFT) and ab initio molecular dynamic (AIMD) simulations. The adsorption of H 2 shows the mixed preference of H adsorption sites on the Pt(111), while the fcc adsorption site is dominant for H on the Pd(111). When benzaldehyde is added to the systems, we observe a strong reduction of benzaldehyde on charged Pd (111) surface compared with that on neutral surface. In contrast, charged state of the Pt(111) surface does not change their interaction. Subsequent hydrogenation reaction of benzaldehyde over Pd(111), proceeding via Langmuir-Hinshelwood mechanism, is affected by two major factors: the presence of H 2 O solvent and surface charge. The presence of H 2 O solvent greatly reduces the activation energy of C H and O H bond formation during the hydrogenation process. Furthermore, the hydrogenation step via C H bond formation is preferred thermodynamically and kinetically over O H bond formation during thermocatalytic hydrogenation, while the opposite trend holds true during electrocatalytic hydrogenation. [ABSTRACT FROM AUTHOR]

Published

2022

5. Electro-reduction of organics on metal cathodes: A multiscale-modeling study of benzaldehyde on Au (111).

Author

Nguyen, Manh-Thuong, Akhade, Sneha A., Cantu, David C., Lee, Mal-Soon, Glezakou, Vassiliki-Alexandra, and Rousseau, Roger

Subjects

*BENZALDEHYDE, *SCANNING tunneling microscopy, *CATHODES, *ELECTRIC batteries, *ELECTRIC currents, *MULTISCALE modeling, *ANODES

Abstract

• We study the electro-reduction of benzaldehyde on Au(111) using multiscale modeling. • Electrode charge density decreases the surface coverage of benzaldehyde on Au(111). • Solvents with alcohols increase the coverage of benzaldehyde on the catalyst. • The Butler-Volmer behavior is recaptured using scanning tunneling microscope theory. • Solvent compositions play a key role in the electro-reduction of organic molecules. We present a multiscale modeling study on the electro-reduction of benzaldehyde (BZY) on Au(111) under realistic electrochemical conditions. To model the electrochemical cell, we adopt a capacitor model in which complex solvents are confined between a Au cathode and a carbon anode. Classical molecular dynamics simulations reveal that electrode charge density and the presence of alcohol show strong effects on the density, adsorption geometry and dynamics of benzaldehyde on the Au electrode. Under charging conditions, the surface concentration of benzaldehyde on the Au electrode decreases, while the content of other species increases. Finally, we proposed a scheme that correlates the electric current running through the Au/solvent interface with the applied bias. This study provides a molecular level understanding of how solvent composition, in this case water/alcohol content, controls the activity of electrocatalytic hydrogenation [ABSTRACT FROM AUTHOR]

Published

2020