Mert Taskin scite author profile

Immobilization of molecular catalysts on electrode surfaces using host–guest interactions

Sévery

¹

,

Szczerbiński

²

,

Taskin

³

et al. 2021

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The strategy of anchoring molecular catalysts on electrode surfaces combines the high selectivity and activity of molecular systems with the practicality of heterogeneous systems. The stability of molecular catalysts is, however, far less than that of traditional heterogeneous electrocatalysts, and therefore a method to easily replace anchored molecular catalysts that have degraded could make such electrosynthetic systems more attractive. Here, we apply a non-covalent "click" chemistry approach to reversibly bind molecular electrocatalysts to electrode surfaces via host-guest complexation with surface-anchored cyclodextrins. The host-guest interaction is remarkably strong and allows the flow of electrons between the electrode and the guest catalyst. Electrosynthesis in both organic and aqueous media was demonstrated on metal oxide electrodes, with stability on the order of hours. The catalytic surfaces can be recycled by controlled release of the guest from the host cavities and readsorption of fresh guest. This strategy represents a new approach to practical molecular-based catalytic systems. 3Molecular electrocatalysts can exhibit surprisingly high activities and selectivities that are unmatched by most heterogeneous catalysts. 1,2 Therefore, the development of robust immobilization strategies for these molecular species on electrode surfaces is of great interest if these molecular catalytic activities and selectivities are to be transferred to more practical heterogeneous electrosynthetic systems, 3 which have already shown promising results for CO 2 reduction, water reduction and water oxidation in the context of storage of renewable energy. [4][5][6] Over the past decades, many immobilization strategies have been developed, 7 which can be categorized into covalent binding (achieved by adding anchoring groups such as carboxylate to the catalysts), 8 non-covalent binding (pi-stacking on carbon-based electrodes) 9,10 and polymerization-based binding. [11][12][13] Here, we report a new strategy for surface immobilization of molecular electrocatalysts, which relies on a non-covalent "click" chemistry approach to bind molecular species in welldefined sites on electrode surfaces. 14 The binding of electroactive molecular guests into molecular pockets by means of host-guest complex (HGC) formation has previously been studied by several groups, including those of Stoddart and Kaifer, 15 Reinhoudt 16,17 and Huskens. 18 Liu et al. reported the HGC-formation on gold surfaces with the C 60 monoanion as guest, which was found to be electrochemically stable over prolonged durations. 19 Light-induced electron transfer to and from dye molecules bound via the HGC approach was also demonstrated by Freitag and Galoppini. 20,21 The group of Sun demonstrated the use of HGC to improve electron transfer between a molecular catalyst and a dye molecule bound onto TiO 2 . 22 Among the diverse class of host molecules, cyclodextrins, cucurbiturils and calixarenes are the most studied for HGC formation on different surfaces. 23,24 For cy...

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A versatile platform for graphene nanoribbon synthesis, electronic decoupling, and spin polarized measurements

Cahlík

¹

,

Liu

²

,

Zengin

³

et al. 2023

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Host-Guest Interactions on Electrode Surfaces for Immobilization of Molecular Catalysts

Sévery¹,

Szczerbiński²,

Taskin³

et al. 2020

Preprint

1

0

View full text Add to dashboard Cite

The strategy of anchoring molecular catalysts on electrode surfaces combines the high selectivity and activity of molecular systems with the practicality of heterogeneous systems. The stability of molecular catalysts is, however, far less than that of traditional heterogeneous electrocatalysts, and therefore a method to easily replace anchored molecular catalysts that have degraded could make such electrosynthetic systems more attractive. Here, we apply a non-covalent “click” chemistry approach to reversibly bind molecular electrocatalysts to electrode surfaces via host-guest complexation with surface-anchored cyclodextrins. The host-guest interaction is remarkably strong and allows the flow of electrons between the electrode and the guest catalyst. Electrosynthesis in both organic and aqueous media was demonstrated on metal oxide electrodes, with stability on the order of hours. The catalytic surfaces can be recycled by controlled release of the guest from the host cavities and readsorption of fresh guest. This strategy represents a new approach to practical molecular-based catalytic systems.

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Formation of NixFe3−xO4 on Fe3
Taskin
¹
,
Novotný
²
,
Hengsberger
³

et al. 2023
Phys. Rev. Materials
2
0
0
0
View full text Add to dashboard Cite

Host-Guest Interactions on Electrode Surfaces for Immobilization of Molecular Catalysts

Sévery¹,

Szczerbiński²,

Taskin³

et al. 2020

Preprint

0

View full text Add to dashboard Cite

The strategy of anchoring molecular catalysts on electrode surfaces combines the high selectivity and activity of molecular systems with the practicality of heterogeneous systems. The stability of molecular catalysts is, however, far less than that of traditional heterogeneous electrocatalysts, and therefore a method to easily replace anchored molecular catalysts that have degraded could make such electrosynthetic systems more attractive. Here, we apply a non-covalent “click” chemistry approach to reversibly bind molecular electrocatalysts to electrode surfaces via host-guest complexation with surface-anchored cyclodextrins. The host-guest interaction is remarkably strong and allows the flow of electrons between the electrode and the guest catalyst. Electrosynthesis in both organic and aqueous media was demonstrated on metal oxide electrodes, with stability on the order of hours. The catalytic surfaces can be recycled by controlled release of the guest from the host cavities and readsorption of fresh guest. This strategy represents a new approach to practical molecular-based catalytic systems.

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Mert Taskin

Immobilization of molecular catalysts on electrode surfaces using host–guest interactions

A versatile platform for graphene nanoribbon synthesis, electronic decoupling, and spin polarized measurements

Host-Guest Interactions on Electrode Surfaces for Immobilization of Molecular Catalysts

Formation of NixFe3−xO4 on Fe3
Taskin
¹
,
Novotný
²
,
Hengsberger
³

et al. 2023
Phys. Rev. Materials
2
0
0
0
View full text Add to dashboard Cite

Host-Guest Interactions on Electrode Surfaces for Immobilization of Molecular Catalysts

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About

Mert Taskin

Immobilization of molecular catalysts on electrode surfaces using host–guest interactions

A versatile platform for graphene nanoribbon synthesis, electronic decoupling, and spin polarized measurements

Host-Guest Interactions on Electrode Surfaces for Immobilization of Molecular Catalysts

Formation of NixFe3−xO4 on Fe3Taskin1, Novotný2, Hengsberger3 et al. 2023Phys. Rev. Materials2000View full textAdd to dashboardCite

Host-Guest Interactions on Electrode Surfaces for Immobilization of Molecular Catalysts

Contact Info

Product

Resources

About

Formation of NixFe3−xO4 on Fe3
Taskin
¹
,
Novotný
²
,
Hengsberger
³

et al. 2023
Phys. Rev. Materials
2
0
0
0
View full text Add to dashboard Cite