Litcius/Paper detail

Tailoring the Optical Properties of Nanoscale-Thick Metal–Dielectric Ag–SiO<sub>2</sub> Nanocomposite Films for Precision Optical Coating Integration

Lirong Sun, John T. Grant, John G. Jones, Neil R. Murphy, Jonathan P. Vernon, Peter R. Stevenson

2023ACS Applied Nano Materials11 citationsDOI

Abstract

Thin-metal films can be challenging to process at ultrathin thicknesses (≲10 nm) due to poor wetting (or surface tension compatibility) at dielectric interfaces. Typical thickness dimensions required to induce the onset of coalescence is usually ≳20 nm. Films <20 nm in thickness can result in non-ideal process-dependent film uniformity and morphology that prevent controlled and repeatable ultrathin-film optical properties and behavior. Such thickness limitations undesirably constrain the design and integration of thin-metal films into high-precision multilayer optical coatings (e.g., narrow bandpass filters and induced transmission filters). The co-sputtering of nanocomposite metal–dielectric films offers an appealing route toward ultrathin film coalescence and tailorable optical properties to achieve high-precision optical performance at significantly reduced film thicknesses (e.g., as compared to conventional all-dielectric multilayer optical media). In this work, silver (Ag) nanoparticles and contiguous Ag networks embedded in a silicon dioxide (SiO 2 ) matrix were prepared at ambient substrate temperature via magnetron co-sputtering in a controlled pure argon atmosphere. We show that the structural features and optical properties of nanocomposite Ag–SiO 2 films can be manipulated by varying the co-sputtering duration at ∼3–10 nm film thicknesses. Here, the Ag material phase ranges in structure from dispersed nanoparticles to contiguous partially coalesced networks. A distinct optical response transition occurs upon Ag phase transition from nanoparticles to the partially coalesced network. Large differences in the measured optical intensity are observed at these reduced film thicknesses: maximum Δ T = 67%, Δ R = 28%, and Δ A = 46% in the visible and near-infrared regions. Overall, our work shows the tailoring of ultrathin-metal-film optical properties (i.e., the refractive index, n, and extinction coefficient, k ) and is expected to provide implementable methodologies toward the design, deposition, and integration of next-generation complex index multilayer optical filters and mirrors exhibiting enhanced precision spectral performance.

Topics & Concepts

Materials scienceNanocompositeDielectricSputteringThin filmSputter depositionNanoparticleOptical coatingCoatingOptoelectronicsComposite materialNanotechnologyOptical Coatings and GratingsThin-Film Transistor TechnologiesFluid Dynamics and Thin Films