Au-Pt Core-Shell Nanoemitters on Silicon for Photoelectrochemical Solar Energy Conversion

TL;DR

This paper reports the development of Au-Pt core-shell nanoemitters on silicon that enhance light absorption and improve photoelectrochemical solar energy conversion efficiency, achieving up to 8.7% efficiency.

Contribution

It introduces a novel fabrication method for Au-Pt heterojunction nanoemitters on silicon, combining electrodeposition and nanostructuring for improved solar energy conversion.

Findings

Enhanced light absorption confirmed by simulations.

Achieved up to 8.7% solar-to-energy conversion efficiency.

Potential for further optimization discussed.

Abstract

Plasmonic Au-Pt core-shell heterojunctions were prepared as nanoemitters at pre-structured porous SiO2/Si interfaces. Silicon templates were obtained by oscillatory photocurrent cycles in fluoride containing solutions. Local formation of noble metal heterocontacts was realized by electrodeposition of i) Pt nuclei at Si pore tips, ii) spherical Au deposits on Pt nuclei and iii) protective Pt shells. Enhanced light absorption of these Au-Pt/SiO2/Si nanoarchitectures is deduced from Mie scattering analysis and Finite Difference Time Domain simulations. Operation of the photoelectrodes in I-/I3- redox electrolytes confirms the potential advantage of the concept over monometallic Pt emitter interfaces. Efficiencies for solar light to energy conversion up to 8.7% were already obtained. Further optimization of the device is discussed in terms of interface state formation at the SiO2/Si boundary and Schottky-type junction properties.