AI Article Synopsis
- Novel methods for creating platinum (Pt) nanostructured electrodes show promise in enhancing electrochemical performance, but existing techniques often require expensive or time-consuming equipment.
- Researchers successfully developed a one-step, template-free electrodeposition method for producing Pt nanostructures, demonstrating that factors like deposition parameters and the ratio of sulfuric acid to chlorocomplexes affect the size and shape of the nanostructures.
- The resulting Pt nanostructures significantly improve electrochemical properties, exhibiting higher sensitivity in biosensors for glucose detection and maintaining excellent electrocatalytic activity, indicating potential applications in monitoring human metabolism.
Article Abstract
Novel methods to obtain Pt nanostructured electrodes have raised particular interest due to their high performance in electrochemistry. Several nanostructuration methods proposed in the literature use costly and bulky equipment or are time-consuming due to the numerous steps they involve. Here, Pt nanostructures were produced for the first time by one-step template-free electrodeposition on Pt bare electrodes. The change in size and shape of the nanostructures is proven to be dependent on the deposition parameters and on the ratio between sulphuric acid and chloride-complexes (i.e., hexachloroplatinate or tetrachloroplatinate). To further improve the electrochemical properties of electrodes, depositions of Pt nanostructures on previously synthesised Pt nanostructures are also performed. The electroactive surface areas exhibit a two order of magnitude improvement when Pt nanostructures with the smallest size are used. All the biosensors based on Pt nanostructures and immobilised glucose oxidase display higher sensitivity as compared to bare Pt electrodes. Pt nanostructures retained an excellent electrocatalytic activity towards the direct oxidation of glucose. Finally, the nanodeposits were proven to be an excellent solid contact for ion measurements, significantly improving the time-stability of the potential. The use of these new nanostructured coatings in electrochemical sensors opens new perspectives for multipanel monitoring of human metabolism.
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|---|---|
| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC4626773 | PMC |
| http://dx.doi.org/10.1038/srep15277 | DOI Listing |
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