The authors theoretically investigate quantum confinement and transition energies in quantum wells (QWs) asymmetrically positioned in wrinkled nanomembranes. Calculations reveal that the wrinkle profile induces both blue-and redshifts depending on the lateral position of the QW probed. Relevant radiative transistions include the ground state of the electron (hole) and excited states of the hole (electron). Energy shifts as well as stretchability of the structure are studied as a function of wrinkle amplitude and period. Large tunable bandwidths of up to 70 nm are predicted for highly asymmetric wrinkled QWs.Wrinkled (or buckled) nanomembranes 1 have recently been investigated to provide stretchability/bendability for a broad range of applications such as integrated circuits, 2 magnetoelectronics, 3 photodetectors, 4 solar cells 5 and light emitting diodes. 6 Incorporating quantum wells (QWs) into a flexible thin membrane, for instance, enables strain to modify the magnetoresistive 7 or optical properties 8 of the structure. In particular, large energy shifts caused by strain modulations might be interesting for broadband QW detectors and emitters. 9 However, there is little work elucidating the limits and impact of modulated strain on the emission properties of wrinkled nanomembranes incorporating QWs.In this work, we study the electronic and optical properties of wrinkled nanomembranes incorporating QWs at different positions away from the mechanical neutral plane of the nanomembrane. The wrinkle shape provides strain in both concave and convex regions, which alters the bandedge potential and causes a pronounced lateral variation of the transition energies. Large wavelength tunability is predicted and scaling properties of the structure are discussed.As a typical example, we consider a nanomembrane of total thickness d consisting of an In Ga As QW layer ( ) with initial misfit strain sandwiched between two GaAs barrier layers with variable thicknesess and . A total thickness of is assumed and the GaAs barrier thickness is always larger than 10 nm in order to ensure good carrier confinement in the QW layer. 10 The nanomembrane can be fully 2 or partially 4 bonded to a prestrained flexible substrate and upon release of the prestrain, it deforms into wrinkles, which can be described by , where and are wrinkle amplitude and wavenumber (