Thermosensitive fluorescent nanoparticles seeded in de-ionized water have demonstrated the presence of strong thermal gradients in two-phase cavitating microflows. A thermal mapping has been made possible by the use of a confocal microscope, focusing and scanning over the three dimensions of a microchannel interrupted by a microdiaphragm. Working with DI water with flow rates of around 1 liter/ hour, cavitation is here the consequence of high shear rates downstream a diaphragm of hydraulic diameter of ≈ 77 µm. A thermal gradient ≈ 105 K/m has been detected only when the two-phase flow is present. It is located in vortical structures associated with eddies in the shear layers. Thermal profiles have been recorded at different heights of the channel, in the area where the flow exhibits the strongest thermal gradient. The increase of temperature is associated with an increase of the void fraction. That last parameter is reached by considering the spatial variations of the thermally - normalized intensity of the emitting nanoprobes. We believe that overheating is the consequence of the breakdown of large structures into small structures, and of the ultimate conversion of kinetic energy into heat. As the onset of cavitation goes with a drop of the flowrate, a model combining the corresponding hydrodynamic losses to the thermal effects has been established. It demonstrates that the intensity of the thermal gap is enhanced by the microsizes of the device. Meanwhile, the effect of heat transfer due to phase change need to be considered.