The aipes Research Group proposes a comprehensive and multidisciplinary effort to investigate the processing, properties, and application of silicon nanomembranes (SiNMs) to achieve adaptive intelligent photonic/electronic systems (Si-AIPES) with novel function.

SiNMs are unique in that they allow the surmounting of technology barriers that clearly have limited rigid Si. In particular, SiNMs offer singular opportunities in nanophotonics/electronics platforms that appear to be unachievable any other way. SiNMs are large, extremely thin, defect-free, strained (or unstrained) single-crystal Si (Ge, combinations, etc.) sheets whose thickness to lateral dimension aspect ratio can be likened to that of a bed sheet (but a single crystal nonetheless).

 SiNMs offer the following key technical advantages:
They are very thin (2-3 nm to 1000nm) and flexible, and can be manipulated dynamically.
They are stackable. Multiple transfers will produce membrane heterostructures.
SiNMs can be strain engineered via layers of Si, SiGe, SiGeC, etc., while remaining dislocation-free. Strain engineering allows manipulating the band structure, carrier mobility, dielectric properties, and phonon spectrum of SiNMs.
SiNMs are quite transparent and are processable on both sides.
They are easily transferred to many other hosts without introducing defects.
They can be patterned into many shapes, including nanowires, microtubes, and structures with combinable dimensions from 0D to 3D.
SiNMs are conformable. Devices and circuits made on/in SiNMs can be attached onto shaped (non-flat) hosts.
SiNMs are processable like bulk Si. Thus all manner of Si devices can be fabricated, and high-volume manufacturing is feasible. Because of this versatility, SiNMs offer extensive new opportunities in the dynamic manipulation of light, heat, electric charges, and their combination, all on a very compact and highly configurable scale.