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Enhancing glucose oxidation: exploring 3D Pt nanowire frameworks for electrochemical studies

Enhancing glucose oxidation: exploring 3D Pt nanowire frameworks for electrochemical studies
Enhancing glucose oxidation: exploring 3D Pt nanowire frameworks for electrochemical studies

Here, we report the use of highly reproducible free-standing 3D Pt nanowire frameworks (3D Pt NFs) to investigate the electrochemical oxidation of glucose. To create this unique Pt NFs, we utilize a lipidic bicontinuous cubic phase as a template. The resulting Pt NFs exhibits a unique 3D single diamond morphology with Fd3m symmetry. This intricate structure provides a large surface area and high electrocatalytic efficiency, making it more sensitive to glucose detection. Small Angle X-ray Scattering and Transmission electron microscopy investigations provided valuable insights into the nanoarchitecture of 3D Pt NFs. It highlights the interconnected nature of the nanowires and showcases the potential for optimized electrochemical performance. Very high current densities are registered for the glucose oxidation reactions at 3D Pt NFs during cyclic voltammetry investigations. This knowledge aids in the design and development of advanced electrocatalytic systems, fuel cells, biosensors, and other devices that leverage the unique characteristics of the 3D Pt framework. Graphical abstract: This study explores 3D Pt NFs for electrochemical glucose oxidation. Using a phytantriol template with two non-intersecting aqueous channels (A), Pt is electrodeposited in one channel (B), resulting in the formation of 3D Pt NFs after template washing (C). This approach demonstrates the potential for efficient glucose oxidation in the structured nanowire frameworks. (Figure presented.)

3D nanowire framework, Cyclic voltammetry, Electrooxidation, Glucose, Platinum
0021-891X
2781-2789
Zaman, Tamseel
8e1e3f18-b342-4ccc-af4a-e24e4a27b1d1
Akbar, Samina
161851df-f691-49ef-960c-c2f325c98357
White, Joshua S.
3025791c-ba86-4207-8059-19ff2617122c
Nandhakumar, Iris
e9850fe5-1152-4df8-8a26-ed44b5564b04
Zaman, Tamseel
8e1e3f18-b342-4ccc-af4a-e24e4a27b1d1
Akbar, Samina
161851df-f691-49ef-960c-c2f325c98357
White, Joshua S.
3025791c-ba86-4207-8059-19ff2617122c
Nandhakumar, Iris
e9850fe5-1152-4df8-8a26-ed44b5564b04

Zaman, Tamseel, Akbar, Samina, White, Joshua S. and Nandhakumar, Iris (2024) Enhancing glucose oxidation: exploring 3D Pt nanowire frameworks for electrochemical studies. Journal of Applied Electrochemistry, 54 (12), 2781-2789. (doi:10.1007/s10800-024-02149-1).

Record type: Article

Abstract

Here, we report the use of highly reproducible free-standing 3D Pt nanowire frameworks (3D Pt NFs) to investigate the electrochemical oxidation of glucose. To create this unique Pt NFs, we utilize a lipidic bicontinuous cubic phase as a template. The resulting Pt NFs exhibits a unique 3D single diamond morphology with Fd3m symmetry. This intricate structure provides a large surface area and high electrocatalytic efficiency, making it more sensitive to glucose detection. Small Angle X-ray Scattering and Transmission electron microscopy investigations provided valuable insights into the nanoarchitecture of 3D Pt NFs. It highlights the interconnected nature of the nanowires and showcases the potential for optimized electrochemical performance. Very high current densities are registered for the glucose oxidation reactions at 3D Pt NFs during cyclic voltammetry investigations. This knowledge aids in the design and development of advanced electrocatalytic systems, fuel cells, biosensors, and other devices that leverage the unique characteristics of the 3D Pt framework. Graphical abstract: This study explores 3D Pt NFs for electrochemical glucose oxidation. Using a phytantriol template with two non-intersecting aqueous channels (A), Pt is electrodeposited in one channel (B), resulting in the formation of 3D Pt NFs after template washing (C). This approach demonstrates the potential for efficient glucose oxidation in the structured nanowire frameworks. (Figure presented.)

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s10800-024-02149-1 - Version of Record
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More information

Accepted/In Press date: 24 May 2024
e-pub ahead of print date: 8 June 2024
Published date: December 2024
Keywords: 3D nanowire framework, Cyclic voltammetry, Electrooxidation, Glucose, Platinum
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Identifiers

Local EPrints ID: 491517
URI: http://eprints.soton.ac.uk/id/eprint/491517
DOI: doi:10.1007/s10800-024-02149-1
ISSN: 0021-891X
PURE UUID: 3dadd8c6-4740-4d5e-955d-9aefed8df972
ORCID for Samina Akbar: ORCID iD orcid.org/0000-0002-9456-3861
ORCID for Iris Nandhakumar: ORCID iD orcid.org/0000-0002-9668-9126

Catalogue record

Date deposited: 25 Jun 2024 16:55
Last modified: 16 Nov 2024 03:07

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Contributors

Author: Tamseel Zaman
Author: Samina Akbar ORCID iD
Author: Joshua S. White
Author: Iris Nandhakumar ORCID iD

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