Thermal conduction becomes less efficient as structures scale down into submicron sizes since phonon-boundary scattering becomes predominant and impede phonons more efficiently than Umklapp scattering. Recent studies indicated that the surface phonon polaritons (SPhPs), which are the evanescent electromagnetic waves generated by the hybridation of the optical phonons and the photons and propagating at the surface of a polar dielectric material surface, potentially serve as novel heat carriers to enhance the thermal performance in micro- and nanoscale devices. We conduct a micro time-domain thermoreflectance (μTDTR) measurement of SiN suspended submicron films to study the contribution of SPhPs to heat transfer. Our experimental demonstrates that stronger TC enhancement exists at high temperatures by decreasing the film thickness, as expected from the contribution of the SPhPs. Meanwhile for thicker films, TC decreases above 600K and is inversely proportional to temperature, presumably due to Umklapp scattering. The results presented here have future applications in the field of heat transfer, thermal management, near-field radiation and polaritonics.