Through this project, overall, we have successfully experimentally demonstrated optically-monitored Rayleigh SAWs and surface skimming acoustic waves on the unconventional platform of cleaved SLs with deeply sub-optical-wavelength nanometer periodicities (Figure 1). The proof-of-principle experiments on a 71 nm GaAs/AlAs SL revealed Rayleigh SAWs and skimming surface bulk waves in the range of 40−70 GHz by a 405/810 nm setup. Subsequently, this pioneer report together with the theoretical analysis ensured the further exploration in sub-THz range. On a platform of Al0.7Ga0.3As/GaAs SLs with only ~18 nm periodicity, a triplet of well-separated ~ 150, 200, 300 GHz coherent acoustic waves were observed by a 354/343 nm setup. They are consistent to the first-order zone-center Rayleigh, transverse and longitudinal modes in the dispersion relation and increase with the diminishing of the SL periodicity. This means that Rayleigh SAWs above 100 GHz, namely, sub-THz SAWs, have been for the first time achieved on the untraditional platform of cleaved SLs, satisfying this project’s main objective. It was also exciting that we even observed surface skimming longitudinal acoustic waves up to 1 THz on cleaved In0.2Ga0.8N/GaN SLs with an 8 nm periodicity. This encourages further development of sub-THz Rayleigh SAWs project towards higher frequency and the understanding of SAW behavior at such regime. Besides, the results revealed the dominant surface skimming transverse mode in opaque SL materials, which was not previously reported. This platform enabled the means to generate and detect surface skimming transverse waves which exhibit promising applications such as inspection of material elasticity and cracks. Importantly, for the SAW transmission at the sub-THz range, they have shown a few µm propagation distance on the Al0.7Ga0.3As/GaAs SLs. Lastly, considerable efforts have been also made on exploring new or optimized optical systems, on optimizing SL constituent layers for SAW transmission, on understanding the impact of oxidation and surface roughness. Our observations build a bridge from GHz towards THz opto-acoustic/acousto-optic transducers. For dissemination, communication, and exploitation, 5 conferences, 1 publication (so far), 1 summer school, 1 european researchers' night, several exhibitions, and further project collaboration were involved.