Illuminated plasmonic metal nanostructures can efficiently convert light into heat at nanoscale dimensions. The heat generated in the nanostructure can be, similarly to light, strongly localized in deep sub-wavelength volumes. Despite the localized heating, generating localized nanoscale temperature spots is challenging due to the diffusive spread of heat which, because the plasmonic nanostructures typically have a much larger thermal conductivity than the surrounding environment, tends to make the temperature uniform within the nanostructure. We tackled this challenge by fully exploiting the photothermal response of free-standing sub-wavelength nanocones under continuous wave illumination. In this respect, a 3D finite element method model was employed to obtain the 3D electric field, heat and temperature distributions. The results demonstrate the possibility to generate deep sub-wavelength localized temperature spots and strong temperature gradients within the nanocone and how size, shape, surrounding environment material, incoming wavelength and polarization provide a way to control and tune the photoinduced temperature gradient.