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Open Access Research Article Just Accepted
Synergistically enhanced ternary Schottky/S-scheme homojunction for ultrasensitive photoelectrochemical sensing
Nano Research
Available online: 20 May 2026
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Currently, constructing heterojunctions to improve photoelectric conversion efficiency represents a highly promising approach for improving the sensitivity in photoelectrochemical (PEC) sensors. Nevertheless, the performance enhancement is often constrained by the lattice mismatch between dissimilar semiconductors. In this work, we introduce a novel synergistic enhancement model based on a Schottky-coupled S-scheme homojunction. By controlling different conditions under the same hydrothermal method, the homojunction of CdS quantum dots grown in-situ on CdS nanorods was synthesized. The homojunction features intimate interfacial contact, a perfectly matched lattice, and an S-scheme carrier pathway, thus increasing the photocurrent response by 17 times. Subsequent integration with gold nanoparticles further amplifies the performance, yielding a synergistic 31-fold improvement. Leveraging this architecture, we demonstrate an ultrasensitive PEC biosensor for the detection of C-reactive protein activity, operating at 0 V bias and without sacrificial agents. This pioneering strategy of combining Schottky junctions with S-scheme homojunctions offers a new direction for advancing photoelectric performance in PEC sensing.

Open Access Perspective Review Issue
Selectivity and stability reshaping high-sensitivity detection boundaries: A technical leap and paradigm shift in semiconductor surface-enhanced Raman scattering
Nano Research 2026, 19(3): 94908347
Published: 11 March 2026
Abstract PDF (3.6 MB) Collect
Downloads:207

This perspective commemorates 50 years of surface-enhanced Raman scattering (SERS) by highlighting the paradigm shift toward rationally designed semiconductor substrates, enabling ultrasensitive and molecule-selective detection. Several enhancement strategies have been developed to effectively modulate the electronic band structure and charge transfer (CT) processes, such as energy level customization, amorphization, quasi-metallization, and morphology control, achieving high enhancement factors with good selectivity and stability. Moreover, semiconductor SERS substrates show broad prospects in the fields of bio-sensing and cancer diagnosis. Nevertheless, standardization gaps in substrate reproducibility and data comparability hinder its widespread adoption. Resolving these challenges through multi-stakeholder collaboration is essential to bridge the technology transfer gap and establish SERS as a core platform for next-generation inspection.

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