# Surface Thermal Gradients Activated by Enhanced Molecular Absorption in   Mid-infrared Vertical Antenna Arrays

**Authors:** Andrea Mancini, Valeria Giliberti, Alessandro Alabastri, Eugenio, Calandrini, Francesco De Angelis, Denis Garoli, Michele Ortolani

arXiv: 1812.07828 · 2018-12-20

## TL;DR

This study demonstrates how vertical nanoantenna arrays can generate significant localized thermal gradients at the surface through enhanced molecular absorption in the mid-infrared, enabling applications in thermoplasmonics.

## Contribution

It introduces a novel thermoplasmonic platform using polymer-embedded vertical antennas for localized heating via SEIRA effect at mid-infrared wavelengths.

## Key findings

- Thermal gradients up to 10 K/μm observed at resonance.
- Potential to reach 1000 K/μm with maximum laser power.
- Thermal gradients can be spatially imaged with nano-photothermal microscopy.

## Abstract

We investigate local heat generation by molecules at the apex of polymer-embedded vertical antennas excited at resonant mid-infrared wavelengths, exploiting the surface enhanced infrared absorption (SEIRA) effect. The embedding of vertical nanoantennas in a non-absorbing polymer creates thermal isolation between the apical hotspot, the locus of heat generation, and the heat sink represented by the substrate. Vibrational mid-infrared absorption by strongly absorbing molecules located at the antenna apex then generates nanoscale temperature gradients at the surface. We imaged the thermal gradients by using a nano-photothermal expansion microscope, and we found values up to 10 K/microm in conditions where the radiation wavelength resonates with both the molecule vibrations and the plasmonic mode of the antennas. Values up to 1000 K/microm can be foreseen at maximum quantum cascade laser power. The presented system provides a promising thermoplasmonic platform for antenna-assisted thermophoresis and resonant mid-infrared photocatalysis.

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Source: https://tomesphere.com/paper/1812.07828