Low-temperature (≤ 350 °C) aluminum-induced layer exchange enables the integration of large-grained polycrystalline silicon–germanium layers into silicon-based optical, electronic, and electromechanical sensors, either in post-processing or at the back-end-of-line of a CMOS flow. We systematically investigate how annealing conditions, metal composition, diffusion control layer, and Al/a-Ge thicknesses influence the crystallization process and the resulting silicon–germanium layer. Our results reveal tunable correlations between process parameters and layer properties, demonstrating that both the crystallinity and the composition of the final layer can be precisely controlled. This work provides practical guidelines for tailoring aluminum-induced layer exchange for silicon–germanium integration across diverse device applications.

Peripheral Nerve Injury (PNI) leads to significant motor and sensory impairments, with limited recovery potential in injuries exceeding 3 cm, Conventional treatments often fail to achieve full functional restoration. Suction-based approaches at lesion sites have demonstrated promising outcomes in nerve regeneration. This work presents a novel wireless, magnetically actuated micropump composed of biodegradable materials, such as poly(octamethylene-maleate(anhydride)citrate) (POMaC), for nerve repair applications. The micropump integrates a magnetic ring within its membrane, enabling deflection under alternating magnetic field (4Hz,pm 150mT), generating a net under-pressure of 1.3 kPa within 8 minutes. It provides a potential solution to facilitate nerve healing.