Flexible Quasi‐2D Perovskite/IGZO Phototransistors for Ultrasensitive and Broadband Photodetection

Wei, Shali; Wang, Fang; Zou, Xuming; Wang, Liming; Liu, Chang; Liu, Xingqiang; Hu, Weida; Fan, Zhiyong; Ho, Johnny C.; Liao, Lei

doi:10.1002/adma.201907527

Cited by 93 publications

(92 citation statements)

References 43 publications

(59 reference statements)

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“…Such value is impressive even comparing to other reported perovskite‐based hybrid devices. [ 24,52–54 ] The gain ( G ), which represents how many effective photocarriers can be generated upon absorbing one photon, can be expressed in terms of responsivity as [ 1 ]

G = \frac{R h c}{e λ}

where R , h , c , e , and λ are responsivity, Planck's constant, light speed, elementary charge, and wavelength of incoming light, respectively. The corresponding maximum gain for RPP/SWCNT device can be calculated to be 4.1 × 10 6 .…”

Section: Resultsmentioning

confidence: 99%

“…This is due to the much longer carrier lifetime in the devices caused by the gradient heterostructure in RPP film. [ 26,28,52 ] High gain photodetectors typically exhibit relatively slow response. [ 15,28 ] Incidentally, although the gain in MAPbI3/SWCNT device is much lower than that in RPP/SWCNT device, it is still higher or comparable to other MAPbI 3 ‐based hybrid phototransistors.…”

Section: Resultsmentioning

confidence: 99%

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High‐Performance Quasi‐2D Perovskite/Single‐Walled Carbon Nanotube Phototransistors for Low‐Cost and Sensitive Broadband Photodetection

et al. 2020

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Quasi‐2D Ruddlesden–Popper perovskites (RPPs) have emerged as promising functional materials for optoelectronics due to the highly tunable optoelectronic properties and have been considered as alternative candidates for semiconductors in photodetectors. However, RPPs normally show low carrier mobilities, which is unfavorable for the performance of photodetectors. Herein, a solution‐processed hybrid phototransistor based on RPP/single‐walled carbon nanotube (SWCNT) heterostructure is reported. A vertical composition gradient is formed upon RPP film preparation, which leads to a gradient type‐II heterojunction in the film. More importantly, the high carrier mobility of SWCNTs can result in ultrahigh responsivity and detectivity of 2 × 106 A W−1 and 7 × 1014 Jones, respectively. In addition, high on/off ratio of ≈103 can be achieved in the phototransistors. Herein, the high potential of RPP/SWCNT hybrid phototransistors as next‐generation photodetectors with superior sensitivity is demonstrated.

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G = \frac{R h c}{e λ}

Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

High‐Performance Quasi‐2D Perovskite/Single‐Walled Carbon Nanotube Phototransistors for Low‐Cost and Sensitive Broadband Photodetection

et al. 2020

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“…Perovskite/indium gallium zinc oxide (IGZO) heterostruture phototransistors have also been reported recently. [ 131–135 ] Wei et al. fabricated a hybrid quasi‐2D perovskite/IGZO heterostructure phototransistor on a PET substrate.…”

Section: Photodetectorsmentioning

confidence: 99%

Emerging Perovskite Materials with Different Nanostructures for Photodetectors

Chen

Zheng

2020

Advanced Optical Materials

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In recent years, solution‐processed lead trihalide perovskites have been widely used as semiconductors in photodetectors with their salient features of tunable direct bandgap, long carrier lifetime, extended diffusion length, and high carrier mobility, etc. For the photodetector application, perovskites with different structures ranging from the traditional 3D perovskites to the emerging 2D perovskites, to 1D nanowires, and to 0D quantum dots, have been synthesized. In this perspective, the recent advances in the strategies of preparing novel lead trihalide perovskites with different nanostructures are summarized together with an overview on their application in photodetectors including photoconductors, photodiodes, and phototransistors. The semiconductor selection and structure–performance relationships of various photodetectors over the past 5 years are discussed comprehensively. Finally, a brief summary as well as an in‐depth discussion regarding the current challenges and perspectives for the future development of perovskite‐based photodetectors is presented.

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“…Organic–inorganic hybrid perovskite has attracted much attention because of its excellent photoelectric properties such as long carrier lifetime, [ 1 ] long diffusion length, [ 2 ] and light absorption coefficient, [ 3 ] leading to broad applications in solar cells, [ 4 ] light‐emitting diodes, [ 5 ] photodetector, [ 6 ] and phototransistors, [ 7 ] etc. To perform high performance for perovskite‐based devices, structural and surface morphology optimization of perovskite, including grain structure, defects, compactness and surface affinity/hydrophobicity, play a crucial role in carrier transport dynamics, which is the key for high‐performance perovskite devices.…”

Section: Figurementioning

confidence: 99%

Quantum Dot Enabled Perovskite Thin Film with Enhanced Crystallization, Stability, and Carrier Diffusion via Pulsed Laser Nanoengineering

Song

Yang

Liu

et al. 2020

Adv Materials Inter

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transport dynamics, which is the key for high-performance perovskite devices. At present, precursor solution additive as a convenient and effective method has been widely used in the structural optimization of perovskite films, [8] such as doping in the perovskite lattice to form bonds, [9] and additives to form hydrogen bonds with perovskites. [10] Quantum dots (QDs) are often doped in perovskite grain boundaries to reduce the boundary barrier for promoting the transport of photogenic carriers. [11] In addition, additives to prevent water/oxygen penetration by forming strong chemical bonds at the interface are important way to improve the stability of perovskite films. [12] Although precursor solution additive method provides an excellent material based for the structural optimization, the current postprocessing methods are limited to fabricate crystalline perovskite films to control their structure and properties, due to the challenges in manipulate the heating/cooling rate, residual stress, and microstructure, such as grain size, intragrain defects, and grain boundary defects. Laser has been widely used in semiconductor processing because of its advantages of monochromatism, coherence, directionality, high speed processing, scalability, wide range control of energy density, and wavelength. The laser-assisted processing technology was developed for rapid processing of perovskite, [13] which can facilitate the postprocessing of perovskite devices with high speed. Moreover, compared with the traditional thermal annealing, the energy consumption of laser treatment is much less. [14] In addition, The temperature control at the material interface, such as grain boundaries, is critical for defect density, and phases, which are important for high-performance perovskite-based optoelectronic devices. However, it is challenging to fine-tune the microstructures in perovskite films with well-controlled grain structure, interface defects, porosity, phase structure, and strains, simultaneously. Here, pulsed laser technology is combined with carbon quantum dots (CQDs) into perovskite absorbers with pore-free, less defect, high crystallinity, enhanced absorption, low stress, and phase-stabilized microstructures. Due to laser-CQD interaction-induced grain boundary microstructure changes, perovskite films can be fabricated with much larger grains (>10 times) than those after thermal annealing. As CQDs are embedded to passivate grain, this leads to reduced grain boundary barrier at the interface, which significantly improve the carrier transportation in perovskite films. The shift of perovskite band to vacuum energy level leads to remarkable improvement of carrier extraction efficiency and lifetime, leading to much higher mobility of photogenerated carriers and diffusion length (>1 μm). The laser-induced thermomechanical momentum significantly enhances crystal interface with hydrophobic perovskite film, resulting in much less residual tensile stress by 20 times and excellent stability. Pulsed-laser-assisted QD additive engineerin...

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Flexible Quasi‐2D Perovskite/IGZO Phototransistors for Ultrasensitive and Broadband Photodetection

Cited by 93 publications

References 43 publications

High‐Performance Quasi‐2D Perovskite/Single‐Walled Carbon Nanotube Phototransistors for Low‐Cost and Sensitive Broadband Photodetection

High‐Performance Quasi‐2D Perovskite/Single‐Walled Carbon Nanotube Phototransistors for Low‐Cost and Sensitive Broadband Photodetection

Emerging Perovskite Materials with Different Nanostructures for Photodetectors

Quantum Dot Enabled Perovskite Thin Film with Enhanced Crystallization, Stability, and Carrier Diffusion via Pulsed Laser Nanoengineering

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