Nanocrystallized CdS beneath the surface of a photoconductor for detection of UV light with picowatt sensitivity

Memory phototransistors based on exponential-association photoelectric conversion law

Ultraweak light detectors have wide-ranging important applications such as astronomical observation, remote sensing, laser ranging, and night vision. Current commercial ultraweak light detectors are commonly based on a photomultiplier tube or an avalanche photodiode, and they are incompatible with microelectronic devices for digital imaging applications, because of their high operating voltage and bulky size. Herein, we develop a memory phototransistor for ultraweak light detection, by exploiting the charge-storage accumulative effect in CdS nanoribbon. The memory phototransistors break the power law of traditional photodetectors and follow a time-dependent exponential-association photoelectric conversion law. Significantly, the memory phototransistors exhibit ultrahigh responsivity of 3.8 × 10⁹ A W⁻¹ and detectivity of 7.7 × 10²² Jones. As a result, the memory phototransistors are able to detect ultraweak light of 6 nW cm⁻² with an extremely high sensitivity of 4 × 10⁷. The proposed memory phototransistors offer a design concept for ultraweak light sensing devices.

CdS nanostructures can enable memory based photodetection by charge-storage accumulative effect. Here, the authors report CdS nanoribbons-based memory phototransistors with high responsivity of 3.8 × 10⁹ A/W and detectivity of 7.7 × 10²² Jones that can detect weak light of 6 nW/cm².

Giant UV-sensitivity of ion beam irradiated nanocrystalline CdS thin films

A highly sensitive UV-detector is devised for the first time from ion beam irradiated nanocrystalline CdS thin films. The sensor exhibits improvements in the responsivity, photosensitivity, and efficiency as a function of ion fluence.