Ultrahigh‐Performance Self‐Powered Flexible Double‐Twisted Fibrous Broadband Perovskite Photodetector

Sun, Haoxuan; Tian, Wei; Cao, Fengren; Xiong, Jie; Li, Liang

doi:10.1002/adma.201706986

Cited by 181 publications

(138 citation statements)

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“…[1][2][3][4] These merits make perovskite as an excellent building block for high-performance photodetectors. The commonly used electron extraction layers in perovskite photodiodes are TiO 2 , [8,9] SnO 2 , [10,11] C 60 , [12,13] and phenyl-C61 butyric acid methyl ester (PCBM). Apart from the integrated system with an energy conversion or harvester unit, [5][6][7] the perovskite photodiode is an excellent alternative in terms of simple structure, light weight, and portability.…”

Section: Photodetectorsmentioning

confidence: 99%

“…Tailoring the gradient bandgap from 0.35 to 1.42 eV, Pan and co-workers synthesized InAs x P 1-x nanosheets for band-selective infrared photodetectors. The commonly used electron extraction layers in perovskite photodiodes are TiO 2 , [8,9] SnO 2 , [10,11] C 60 , [12,13] and phenyl-C61 butyric acid methyl ester (PCBM). [24] In p-i-n structured devices, [25][26][27][28] graded composition (bandgap) is basically used in the main photosensitive layer, for which the narrow bandgap region increases the absorption wavelength range, the large bandgap results in a high voltage output, and graded bandgap structure promotes the carriers transport.…”

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confidence: 99%

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Gradient Energy Band Driven High‐Performance Self‐Powered Perovskite/CdS Photodetector

et al. 2019

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possess lower dark currents and higher detectivities. In spite of great progresses, it is complicated to fabricate composite electronic transport layers (ETLs) with matched crystal lattices and energy levels, otherwise the newly formed interface in the composite may bring about large amounts of defects which act as trap sites and recombination centers.Spatially graded composition (bandgap) is an effective route to continuously tune energy levels and bandgap in semiconductors, [20,21] in which the interfacial recombination is alleviated or removed and a graded built-in potential through the whole bulk is produced, enabling stronger separation capability of photogenerated electron-hole pairs. This concept provides a new platform for designing high-performance optoelectronic devices. For example, Krol and co-workers fabricated the gradient W-doped BiVO 4 as a photoanode of photoelectrochemical cell. [22] Compared to the homogeneously doped BiVO 4 , the continuous built-in band bending induces the directional transfer of photogenerated holes from core to surface and thus increases the carrier separation efficiency to 60%. Tailoring the gradient bandgap from 0.35 to 1.42 eV, Pan and co-workers synthesized InAs x P 1-x nanosheets for band-selective infrared photodetectors. [23] We reported graded CdS x Se 1-x nanobelt solar cells by utilizing continuous stepped energy levels to drive electrons and holes toward opposite direction. [24] In p-i-n structured devices, [25][26][27][28] graded composition (bandgap) is basically used in the main photosensitive layer, for which the narrow bandgap region increases the absorption wavelength range, the large bandgap results in a high voltage output, and graded bandgap structure promotes the carriers transport. Inspired by previous results, with the introduction of gradient built-in band bending at the charge extraction layer/perovskite interface, the energy band offset is expected to provide the driving force for enhanced carrier separation, suppressed electron reflux, and reduced recombination, boosting the performance of perovskite photodetectors.In this work, we present a high-performance self-powered photodetector by integrating perovskite with gradient O-doped CdS nanorod array. For the first time, the continuous builtin band bending is introduced at the charge extraction layer/ perovskite interface to manipulate the transfer behavior of carriers in perovskite photodetectors. The optoelectronic measurements reveal that both the responsivity and the response speed of devices strongly depend on the structure of energy band bending. The optimum gradient O-doped CdS/perovskite Self-powered photodetectors are highly desired to meet the great demand in applications of sensing, communication, and imaging. Manipulating the carrier separation and recombination is critical to achieve high performance. In this paper, a self-powered photodetector based on the integrated gradient O-doped CdS nanorod array and perovskite is presented. Through optimizing the degree of continuous built-in ba...

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Section: Photodetectorsmentioning

confidence: 99%

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confidence: 99%

Gradient Energy Band Driven High‐Performance Self‐Powered Perovskite/CdS Photodetector

et al. 2019

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“…[ 1–13 ] Specifically, self‐powered perovskite photodetector can work without external energy source, depending on a built‐in electric field which can separate the light‐induced carrier. [ 14–16 ] The most studied device type is the vertical heterojunction. However, a vertical device consisting of charge transport layers and top electrodes would cause the loss of the incident light and abundant defects at the interface, degrading the device performance.…”

Section: Introductionmentioning

confidence: 99%

Flexible and Self‐Powered Lateral Photodetector Based on Inorganic Perovskite CsPbI₃–CsPbBr₃ Heterojunction Nanowire Array

Wang

Tian

Cao

et al. 2020

Adv Funct Materials

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Self-powered perovskite photodetectors mainly adopt the vertical heterojunction structure composed of active layer, electron-hole transfer layers, and electrodes, which results in the loss of incident light and interfacial accumulation of defects. To address these issues, a self-powered lateral photodetector based on CsPbI 3 -CsPbBr 3 heterojunction nanowire arrays is designed on both a rigid glass and a flexible polyethylene naphthalate substrate using an in situ conversion and mask-assisted electrode fabrication method. Through adding the polyvinyl pyrrolidone and optimizing the concentration of precursors under the pressure-assisted moulding process, both the crystallinity and stability of perovskite nanowire array are improved. The nanowire array-based lateral device shows a high responsivity of 125 mA W −1 and a fast rise and decay time of 0.7 and 0.8 ms under a self-powered operation condition. This work provides a new strategy to fabricate perovskite heterojunction nanoarrays towards self-powered photodetection.

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“…[27] The detector exhibited an acceptable response speed with rise/decay times of 80/240 µs. [32][33][34][35] However, to the best of our knowledge, PV-type photodetectors employing perovskite MWs/NWs as the photoactive materials have been far scarcely explored to date. ), high-frequency light detection is essentially required.…”

Section: Introductionmentioning

confidence: 99%

Asymmetric Contact‐Induced Self‐Driven Perovskite‐Microwire‐Array Photodetectors

Peng

Fang

et al. 2019

Adv Elect Materials

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Combining both 1D geometry and the features of hybrid perovskite materials, perovskite micro/nanowires have recently attracted particular attention for a variety of optoelectronic device applications. Herein, by taking advantage of the strong built‐in potential induced by asymmetric contact with varied work functions, highly sensitive visible photodetectors based on a CH3NH3PbI3 microwire array that display pronounced photovoltaic activities are reported. These photodetectors afford the capability to work without an external power supply. A representative detector with Au/Ag electrodes achieves a reasonable responsivity of 161.1 mA W−1 with a fast response speed of 13.8/16.1 µs under 520 nm illumination at zero bias. In addition, such a device is also characterized by an ultralow dark current of tens of femtoamps, enabling a high specific detectivity of 1.3 × 1012 Jones. Furthermore, a flexible photodetector is successfully prepared, which shows comparable photoresponse performance and outstanding flexibility and bending durability. Given the good device performance and simple device geometry, the present self‐driven photodetectors hold great promise for future highly sensitive and low‐energy‐consumption photodetection systems.

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Ultrahigh‐Performance Self‐Powered Flexible Double‐Twisted Fibrous Broadband Perovskite Photodetector

Cited by 181 publications

References 40 publications

Gradient Energy Band Driven High‐Performance Self‐Powered Perovskite/CdS Photodetector

Gradient Energy Band Driven High‐Performance Self‐Powered Perovskite/CdS Photodetector

Flexible and Self‐Powered Lateral Photodetector Based on Inorganic Perovskite CsPbI₃–CsPbBr₃ Heterojunction Nanowire Array

Asymmetric Contact‐Induced Self‐Driven Perovskite‐Microwire‐Array Photodetectors

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Ultrahigh‐Performance Self‐Powered Flexible Double‐Twisted Fibrous Broadband Perovskite Photodetector

Cited by 181 publications

References 40 publications

Gradient Energy Band Driven High‐Performance Self‐Powered Perovskite/CdS Photodetector

Gradient Energy Band Driven High‐Performance Self‐Powered Perovskite/CdS Photodetector

Flexible and Self‐Powered Lateral Photodetector Based on Inorganic Perovskite CsPbI3–CsPbBr3 Heterojunction Nanowire Array

Asymmetric Contact‐Induced Self‐Driven Perovskite‐Microwire‐Array Photodetectors

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Flexible and Self‐Powered Lateral Photodetector Based on Inorganic Perovskite CsPbI₃–CsPbBr₃ Heterojunction Nanowire Array