The samples in our research are grown by Molecular Beam Epitaxy (MBE), which can accurately control the property, thickness, and composition of the samples. The group Ⅲ-Ⅴsemiconductor rolled-up micro-tubes are formed by epitaxial growth of the two material layers with different lattice constants on a GaAs substrate. When the strained planar bilayers are released from the substrate by selective etching, they will roll up into a 3D micro-tube. We can almost perfectly fabricate the rolled-up micro-tubes. The diameter of rolled-up micro-tubes depends on the thickness of the strained bilayers and on the built-in strain. We can detect the residual strain of the micro-tubes through the peak-shift of LO phonon frequencies in Micro-Raman spectra as well as the peak-shift of quantum well (QW) in PL spectra in comparison with the tubes and the unreleased areas. The experimental results coincide with a simple elastic model. Moreover, the rolled-up micro-tubes can enhance the luminous intensity of QW and prevent the samples from oxidizing. We had successfully fabricated the devices of conducting InGaAs/GaAs rolled-up micro-tubes. The electrical conductivity of the devices can be increased by at least five times when the strain bilayers are doped with high impurity concentrations. The micro-tubes devices are locally illuminated by a focused laser beam, and can convert the energy of light directly into electricity by the photovoltaic effect just like solar cells. The best energy conversion efficiency is 1.1E-4%, and the devices still have some rooms for improvement. Last but not least, the rolled-up micro-tubes would be a great potential for thermoelectric materials because of their poor thermal conductivity. The micro-tubes devices are locally heated by a hot probe station, and can convert the temperature difference to the electric voltage by the thermoelectric effect. The best thermoelectric figure of merit (ZT) is 0.41 under a conservative estimation, and actually it is much higher than this value. We believe the microtubes devices will show higher thermoelectric conversion efficiency in the near future.