Physical Review Research (Jan 2020)

Large graphene-induced shift of surface-plasmon resonances of gold films: Effective-medium theory for atomically thin materials

  • Md Kamrul Alam,
  • Chao Niu,
  • Yanan Wang,
  • Wei Wang,
  • Yang Li,
  • Chong Dai,
  • Tian Tong,
  • Xiaonan Shan,
  • Earl Charlson,
  • Steven Pei,
  • Xiang-Tian Kong,
  • Yandi Hu,
  • Alexey Belyanin,
  • Gila Stein,
  • Zhaoping Liu,
  • Jonathan Hu,
  • Zhiming Wang,
  • Jiming Bao

DOI
https://doi.org/10.1103/PhysRevResearch.2.013008
Journal volume & issue
Vol. 2, no. 1
p. 013008

Abstract

Read online Read online

Despite successful modeling of graphene as a 0.34-nm-thick optical film synthesized by exfoliation or chemical vapor deposition (CVD), graphene-induced shift of surface-plasmon resonance (SPR) of gold films has remained controversial. Here we report the resolution of this controversy by developing a clean CVD graphene transfer method and extending Maxwell-Garnett effective-medium theory (EMT) to two-dimensional (2D) materials. A SPR shift of 0.24° is obtained and it agrees well with 2D EMT in which wrinkled graphene is treated as a 3-nm graphene/air layered composite, in agreement with the average roughness measured by atomic force microscopy. Because the anisotropic built-in boundary condition of 2D EMT is compatible with graphene's optical anisotropy, graphene can be modeled as a film thicker than 0.34 nm without changing its optical property; however, its actual roughness, i.e., effective thickness, will significantly alter its response to strong out-of-plane fields, leading to a larger SPR shift.