Nanoscale local modification of PMMA refractive index by tip-enhanced femtosecond pulsed laser irradiation

TL;DR

This paper introduces a nanoscale method to modify the surface refractive index of PMMA using tip-enhanced femtosecond laser irradiation, achieving high precision and low energy requirements, with potential applications in nanophotonics.

Contribution

It presents a novel nanoimprinting technique that significantly improves spatial resolution and energy efficiency in refractive index modification of polymers.

Findings

Refractive index modifications with <200 nm lateral size.

Achieved at laser pulse energies <0.5 nJ, two orders of magnitude lower than previous methods.

Method is flexible and applicable to different materials.

Abstract

Investigation techniques based on tip-enhanced optical effects, capable to yield spatial resolutions down to nanometers level, have enabled a wide palette of important discoveries over the past twenty years. Recently, their underlying optical setups are beginning to emerge as useful tools to modify and manipulate matter with nanoscale spatial resolution. We try to contribute to these efforts by reporting a method that we found viable to modify the surface refractive index of polymethyl methacrylate (PMMA), an acrylic polymer material. The changes in the refractive index are accomplished by focusing a femtosecond pulsed near-infrared laser beam on the apex of a metalized nano-sized tip, traditionally used in scanning probe microscopy (SPM) applications. The adopted illumination strategy yields circular-shaped modifications of the refractive index occurring at the surface of the PMMA sample, exhibiting a lateral size <200 nm, under 790 nm illumination, representing a four-fold increase in precision compared to the current state-of-the-art. The light intensity enhancement effects taking place at the tip apex makes possible achieving refractive index changes at low laser pulse energies (<0.5 nJ), which represents two orders of magnitude advantage over the current state-of-the art. The presented nanoimprinting method is very flexible, as it can be used with different power levels and can potentially be operated with other materials. Besides enabling modifications of the refractive index with high lateral resolution, this method can pave the way towards other important applications such the fabrication of photonic crystal lattices or surface waveguides.