What question did this study set out to answer?

The aim is to synthesize chiral silver-platinum hollow nanostructures for enantioselective detection of amino acid enantiomers.

May 9, 2026

Chiral Silver–Platinum Hollow Nanostructures: Seedless Synthetic Strategy and Electrochemical Enantioselective Detection

Key Points

The aim is to synthesize chiral silver-platinum hollow nanostructures for enantioselective detection of amino acid enantiomers.
Used seedless synthetic strategy to form Ag-rich nanoparticles as sacrificial templates.
Guided the growth of Pt onto these templates to create hollow nanostructures.
Evaluated the effectiveness of the resulting nanotubes in electrochemical detection.
Tryptophan enantiomers were successfully detected using the chiral Ag-Pt hollow nanostructures.
Demonstrated strong electrochemical activity due to the chiral surface properties.

Abstract

-formed Ag-rich nanoparticles and nanowires act as sacrificial templates for subsequent Pt growth, leading to hollow nanostructures with Ag-rich inner and Pt-rich chiral surfaces. The growth mechanism can be extended to guide the synthesis of similar chiral Ag-Ir hollow nanostructures. The chiral Ag-Pt hollow nanostructures, especially nanotubes, are fully functional for electrochemical enantioselective detection of tryptophan enantiomers. Our work provides a feasible strategy for fabricating catalytically active noble metals with hierarchical chiral nanostructures.

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Chiral Silver–Platinum Hollow Nanostructures: Seedless Synthetic Strategy and Electrochemical Enantioselective Detection

Key Points

Abstract

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