Probing the optical near-field of plasmonic nano structure using scanning thermal microscopy

Scanning thermal microscopy (SThM) enables to obtain thermal characteristic information such as temperature and thermal conductivity from the signals obtained by scanning a thermometer probe over a sample surface. Particularly, the precise control of the thermometer probe makes it possible to study near-field radiative heat transfer by measuring the near-field thermal energy, which implies that when light is used as a local heat source, photothermal energy can be detected from the optical near-field by approaching the probe in the near-field region. In this study, SThM is applied to generate sub-wavelength near-field optical image in the plasmonic grating coupler. Herein, by controlling the surface plasmon polariton generation, we show that the dominant component of SThM signal is from the optical response rather than the thermal response. The obtained near-field optical images have a spatial resolution of 40 nm and signal to noise ratio of up to 19.8. In addition, field propagation images in the Z-direction can be visualised with the precise control of the distance between the thermometer probe and the sample

Automated summary

Scanning thermal microscopy (SThM) allows for the measurement of thermal characteristic information from signals obtained by scanning a thermometer probe over a sample surface. In this study, SThM is used to generate sub-wavelength near-field optical images in a plasmonic grating coupler, and it is shown that the dominant component of the SThM signal is from the optical response rather than the thermal response.