Abstract
Flexible photonic crystal slabs with an area of 2 cm2 are fabricated by nanoimprint replication of a 400 nm period linear grating nanostructure into a ≈60 µm thick polydimethylsiloxane membrane and subsequent spin coating of a high refractive index titanium dioxide nanoparticle layer. Samples are prepared with different nanoparticle concentrations. Guided-mode resonances with a quality factor of Q ≈ 40 are observed. The highly flexible nature of the membranes allows for stretching of up to 20% elongation. Resonance peak positions for unstretched samples vary from 555 to 630 nm depending on the particle concentration. Stretching results in a resonance shift for these peaks of up to ≈80 nm, i.e., 3.9 nm per % strain. The color impression of the samples observed with crossed-polarization filters changes from the green to the red regime. The high tunability renders these membranes promising for both tunable optical devices as well as visualization devices.
Highlights
Photonic crystal slabs consist of a guiding layer with high refractive index on a nanostructured substrate
We investigated the tunability of flexible photonic crystal membranes fabricated by nanoreplication of a linear grating master into a ≈60 μm thick membrane and subsequent spin coating of a TiO2 nanoparticle waveguide layer
The resonance wavelength is adjustable from 555 to 630 nm during the fabrication process by varying the concentration of nanoparticles in the solution used for spin coating
Summary
Photonic crystal slabs ( called resonance waveguide gratings) consist of a guiding layer with high refractive index on a nanostructured substrate. We conducted an in-depth study of flexible photonic crystal membranes with varying nanoparticle concentrations and different grating properties.
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