Ultrasensitive 1D field-effect phototransistor: CH3NH3PbI3 nanowire sensitized individual carbon nanotube

Abstract

Field-effect phototransistors were fabricated based on individual carbon nanotubes (CNTs) sensitized by CH3NH3PbI3 nanowires (MAPbI3NW). These devices represent light responsivities of R=7.7x105 A/W at low-lighting conditions in the nWmm-2 range, unprecedented among CNT-based photo detectors. At high incident power (~1 mWmm-2), light soaking results in a negative photocurrent, the device turns insulating. We interpret the phenomenon as a result of efficient electron-hole separation and charge transfer of holes from the perovskite to the carbon nanotube, which improves conductance by increasing the number of carriers, but leaves electrons behind. At high illumination intensity the random electrostatic potential of these quench the mobility in the nanotube. The single CNT device geometry allows the local study of the MAPbI3NW/CNT interface for metallic and semiconducting CNTs separately. Infrared and Raman spectroscopy studies of CNT-CH3NH3PbI3 composites revealed that photo-doping takes place at the interface.