<p>Circularly polarized light (CPL) detection is critical to emerging technologies in optical communication, chiral sensing, and bio-inspired imaging. However, current devices rely on intrinsically chiral semiconductors that are synthetically complex and costly to scale. Here, we demonstrate robust CPL detection in achiral organic semiconductors by exploiting chiral plasmonic resonance (CPR). A self-assembled monolayer of L-phenylalanine–dified gold nanoparticles imparts optical chirality to adjacent semiconductors while enhancing photocurrent through plasmon-induced hot-carrier processes. The resulting hybrid devices exhibit nearly tenfold responsivity enhancement and a high dissymmetry factor of 0.35 at 515 nm. Mechanistic analysis reveals a field-driven, hot-carrier-assisted route to helicity sensitivity. This solution-processable approach merges plasmonic chirality with organic semiconductor versatility, providing a scalable platform for next-generation on-chip chiroptoelectronic and polarization-imaging technologies.</p>

错误:搜索内容不能为空,请输入英文关键词
错误:关键词超出字数限制,请精简
高级检索

Circularly polarized light detection in achiral organic semiconductors via chiral plasmonic resonance

  • Wenxuan Chang,
  • Siyuan Zhang,
  • Xianfeng Shen,
  • Rongjiao Zhu,
  • Rongjin Li,
  • Wenping Hu

摘要

Circularly polarized light (CPL) detection is critical to emerging technologies in optical communication, chiral sensing, and bio-inspired imaging. However, current devices rely on intrinsically chiral semiconductors that are synthetically complex and costly to scale. Here, we demonstrate robust CPL detection in achiral organic semiconductors by exploiting chiral plasmonic resonance (CPR). A self-assembled monolayer of L-phenylalanine–dified gold nanoparticles imparts optical chirality to adjacent semiconductors while enhancing photocurrent through plasmon-induced hot-carrier processes. The resulting hybrid devices exhibit nearly tenfold responsivity enhancement and a high dissymmetry factor of 0.35 at 515 nm. Mechanistic analysis reveals a field-driven, hot-carrier-assisted route to helicity sensitivity. This solution-processable approach merges plasmonic chirality with organic semiconductor versatility, providing a scalable platform for next-generation on-chip chiroptoelectronic and polarization-imaging technologies.