A high-performance 4H-SiC p-i-n photodetector for visible-blind ultraviolet (UV) applications has been designed and fabricated. The electrical and optical characteristics were measured at room temperature. The photodetector suffered from significant dark current of 2.5 pA/mm2 at reverse bias of 5 V, and the UV light photocurrent was larger than four orders of magnitude higher than the dark current. The built-in potential and the unintentional i-layer doping concentration were obtained from capacitance-voltage (C-V) measurements. The spectral peak responsivity of the detector reached 0.13 A/W at a wavelength of 270 nm, corresponding to a maximum external quantum efficiency of ∼61%. And the ratio of responsivity at 270 nm to that at 380 nm was >103. The characteristics imply that the photodetector has a great improved ultraviolet-visible rejection ratio which is needed for ultraviolet signal detection.
Scintillators that convert ionization radiation photons
to UV–visible
photons have attracted extraordinary attention. Traditional scintillators
are associated with a vacuum photomultiplier tube that faces strict
constraints of fragility, magnetic fields, and operated voltage, or
coupled to a silicon photomultiplier (SiPM) with optical silicone
grease. Here, we report a high-performance radiation detector with
an indirect photon-to-photon conversion radiation detection model
based on perovskite single crystals (SCs), where perovskite SCs have
been directly integrated into the window of SiPM by using the solution
growth method at low temperature. Tunable X (γ)-ray excited
light emission in the range of 414 to 600 nm is obtained with different
concentrations of Br doping, which greatly matches the response wavelength
of SiPM. Small Br-doped CH3NH3PbBr0.05Cl2.95 SCs exhibit high transmittance and weak self-absorption,
resulting in improved scintillation light emissions. Moreover, we
have successfully collected a 137Cs source gamma-ray pulse
height spectrum with the SiPM readout. The MAPbBr0.05Cl2.95 scintillator exhibits a decay time of 0.14 ± 0.02
ns and a light yield of 18 000 photons/MeV with an energy resolution
of 10.5 ± 0.4% at 662 keV. The results indicate that the CH3NH3PbBr
x
Cl3–x
perovskite SCs could enable the next generation
of low-cost, fast, and fine-energy resolution scintillators.
Halide funnel-typed perovskite materials have been synthesized by simply solution-processed method. This gradient heterostructure materials have been investigated that helpful for charges radiative recombination and suppress non-radiative recombination in the interfaces.
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