All‐Inorganic CsPbBr₃ Perovskite Nanocrystals/2D Non‐Layered Cadmium Sulfide Selenide for High‐Performance Photodetectors by Energy Band Alignment Engineering

Abstract: Perovskites have attracted intensive attention as promising materials for the application in various optoelectronic devices due to their large light absorption coefficient, high carrier mobility, and long charge carrier diffusion length. However, the performance of the pure perovskite nanocrystals-based device is extremely restricted by the limited charge transport capability due to the existence of a large number of the grain boundary between perovskite nanocrystals. To address these issues, a high-performanc… Show more

“…5(c). 13,15,28,38,46,[59][60][61]66,67,69,[71][72][73] The detailed performances of related photodetector devices are listed in Table S2 (ESI †). Compared with the most carefully designed individual CsPbBr 3 wire and hybrid photodetectors, the performance of our photodetectors modified with QDs has remarkable advantages.…”

“…The photoelectric conversion efficiency obtained in this work under a 5 V bias voltage is much greater than that of most present CsPbBr 3 -based photodetectors, even at a much higher bias voltage. 13,38,[59][60][61][64][65][66][67][68][69][70][71][72][73][74][75] In addition, the detectivity (D*) of the CdS@Cd x Zn 1Àx S gradient-alloyed QD-decorated CsPbBr 3 photodetector is increased to 1.62 Â 10 13 Jones, and the response time is reduced to 330 ms. In consequence, a physical model based on band energy theory was developed to illustrate the physical mechanism of these unique enhancement phenomena.…”

A high-responsivity CsPbBr₃ nanowire photodetector induced by CdS@Cd_xZn_1−xS gradient-alloyed quantum dots

“…5(c). 13,15,28,38,46,[59][60][61]66,67,69,[71][72][73] The detailed performances of related photodetector devices are listed in Table S2 (ESI †). Compared with the most carefully designed individual CsPbBr 3 wire and hybrid photodetectors, the performance of our photodetectors modified with QDs has remarkable advantages.…”

“…The photoelectric conversion efficiency obtained in this work under a 5 V bias voltage is much greater than that of most present CsPbBr 3 -based photodetectors, even at a much higher bias voltage. 13,38,[59][60][61][64][65][66][67][68][69][70][71][72][73][74][75] In addition, the detectivity (D*) of the CdS@Cd x Zn 1Àx S gradient-alloyed QD-decorated CsPbBr 3 photodetector is increased to 1.62 Â 10 13 Jones, and the response time is reduced to 330 ms. In consequence, a physical model based on band energy theory was developed to illustrate the physical mechanism of these unique enhancement phenomena.…”

A high-responsivity CsPbBr₃ nanowire photodetector induced by CdS@Cd_xZn_1−xS gradient-alloyed quantum dots

“…The device shows a rise and fall duration of 730 and 620 µs, respectively (Figure 3f), comparable with other fast photoresponse of 2D materials reported previously. [42][43][44][45][46][47][48][49] Next, we study the enhancement on the photovoltaic effect by ferroelectric polarization. It has been demonstrated that α-In 2 Se 3 is a ferroelectric n-type semiconductor with a strong coupling effect between resistance and ferroelectric polarization.…”

A Ferroelectric p–i–n Heterostructure for Highly Enhanced Short‐Circuit Current Density and Self‐Powered Photodetection

“…To study the energy level alignment of the PbSe/ZnO heterostructure, we first employed UPS measurements (Figure S11a–c). The work function (WF) is expressed as: WF = h ν – E onset , , where h ν is the incident photon energy of 21.22 eV and E onset stands for the onset level of the UPS spectra. Thus, the energy of Femi level ( E F ) and the difference between E F and valence band maximum ( E VBM ) can be calculated to be 4.71 and 0.82 eV, respectively (Figure S11b,c).…”

Room-Temperature Direct Synthesis of PbSe Quantum Dot Inks for High-Detectivity Near-Infrared Photodetectors