Flexible optoelectronic devices provide new functionalities and have the potential to open up a new branch of industry. In particular, flexible and energy efficient devices such as light emitting diodes (LEDs) but also photovoltaic and piezoelectric energy harvesters are today a topic of intense research, motivated by their applications such as portable battery chargers, rollable displays or light sources, bio-medical devices, etc. In addition to the device efficiency, the weight and the transportability are also important factors together with the device cost. Therefore, the device flexibility and integration on light cheap supports such as plastic or even textile fabric, which can withstand strong deformations without breaking, is desirable. These flexible energy harvesters and light emitters have the potential of providing access to electricity and lighting in remote regions without grid connection.
In this context, the main objective of the Nano Harvest project is to develop a new class of flexible optoelectronic devices combining polymer films with semiconductor nanowires. The idea is to enable substrate-free devices by encapsulating semiconductor nanowires into polymers, removing them from their growth substrate, functionalizing and assembling the membranes. With this versatile transfer approach flexible light emitters, photovoltaic and piezoelectric converters can be realized. The technology can also be applied to other devices such as photodetectors. One advantage is to combine nanowire/polymer membranes with different functionalities by stacking them. Thus material combinations unavailable with monolithic nanowire growth can be achieved. By stacking together free-standing polymer-embedded nanowires, a multi-bandgap solar cell can be realized and applied to almost any supporting material such as plastic, metal foil or fabrics. Multi-layered flexible and compact piezo-generators based on ordered arrays of nanowire heterostructures can be produced. Multi-colour light emitting diodes combining Red, Green and Blue emitters can be fabricated. The crucial ingredient and also the common basis for all these devices are the advanced nanowire heterostructures with new control-by-design functionalities. Nanoscale engineering and in-depth understanding of physical phenomena in nanowires open the way to reach high device efficiency.