Measurement of Near-Field Radiative Heat Transfer at Deep Sub-Wavelength Distances using Nanomechanical Resonators

Near-field radiative heat transfer (NFRHT) measurements often rely on custom microdevices that can be difficult to reproduce after their original demonstration. Here we study NFRHT using plain silicon nitride (SiN) membrane nanomechanical resonators?a widely available substrate used in applications such as electron microscopy and optomechanics?and on which other materials can easily be deposited. We report measurements down to a minimal distance of 180 nm between a large radius of curvature (15.5 mm) glass radiator and a SiN membrane resonator. At such deep sub-wavelength distance, heat transfer is dominated by surface polariton resonances over a (0.25 mm)(2) effective area, which is comparable to plane-plane experiments employing custom microfabricated devices. We also discuss how measurements using nanomechanical resonators create opportunities for simultaneously measuring near-field radiative heat transfer and thermal radiation forces (e.g., thermal corrections to Casimir forces).

Automated summary

In this study, we investigated near-field radiative heat transfer (NFRHT) using widely available silicon nitride (SiN) membrane nanomechanical resonators. We successfully measured heat transfer at a minimal distance of 180 nm between a glass radiator with a large radius of curvature (15.5 mm) and a SiN membrane resonator.