2022
DOI: 10.1002/admi.202200028
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Flexible Self‐Powered Photoelectrochemical Photodetector with Ultrahigh Detectivity, Ultraviolet/Visible Reject Ratio, Stability, and a Quasi‐Invisible Functionality Based on Lift‐Off Vertical (Al,Ga)N Nanowires

Abstract: electronics, flexible screens, automobile windshield navigation, and IoT (Internet of Things) applications, etc. [1][2] However, the working duration and energy consumption are the key problems that cannot be ignored for the wide applications of optoelectronic devices. Thanks to the ability for long-time working independently without energy consumption, self-powered photodetectors (PDs) can be the indispensable devices to make the detection systems economical and simple. [2,4,6] As the crucial components in th… Show more

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Cited by 15 publications
(9 citation statements)
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“…The J ph approaches saturation at a higher bias voltage of 0.6 V, as shown in Figure S5b, Supporting Information, attributing to saturation photogeneration carriers transport at higher bias voltage. Therefore, we will focus on the performance of ultrathin In reported ultrathin nanomaterial-based aqueous-type PEC UV PDs [31][32][33][34][35][36][37][38][39][40][41][42][43][44][45][46][47][48][49] and are comparable with the record-high performance of recently reported PEC UV PDs, [17] as shown in Table S9, Supporting Information. The ultrahigh UV detection capability and the operation in weak alkaline electrolyte indicate that ultrathin In 2 O 3 NSs hold great prospects for underwater UV communication [12] (more detailed comparison in Table S6, Supporting Information).…”
Section: Photoresponse Of Ultrathin In 2 O 3 Nss Pec Pdsmentioning
confidence: 65%
See 1 more Smart Citation
“…The J ph approaches saturation at a higher bias voltage of 0.6 V, as shown in Figure S5b, Supporting Information, attributing to saturation photogeneration carriers transport at higher bias voltage. Therefore, we will focus on the performance of ultrathin In reported ultrathin nanomaterial-based aqueous-type PEC UV PDs [31][32][33][34][35][36][37][38][39][40][41][42][43][44][45][46][47][48][49] and are comparable with the record-high performance of recently reported PEC UV PDs, [17] as shown in Table S9, Supporting Information. The ultrahigh UV detection capability and the operation in weak alkaline electrolyte indicate that ultrathin In 2 O 3 NSs hold great prospects for underwater UV communication [12] (more detailed comparison in Table S6, Supporting Information).…”
Section: Photoresponse Of Ultrathin In 2 O 3 Nss Pec Pdsmentioning
confidence: 65%
“…The improved spectral selectivity is attributed to the wider bandgap of ultrathin In 2 O 3 NSs originating from the quantum confinement effect. [27] The spectral selectivity and R of ultrathin In 2 O 3 NSs PEC VBUV PDs outperform most reported aqueous-type PEC VBUV PDs, [26,[44][45][46][47][48] as shown in Figure 3c S8, Supporting Information, demonstrating their similar charge transport capability. The fitting R ct of ultrathin In 2 O 3 NSs is 5.797 Ω, which is 63% that of In 2 O 3 NPs, demonstrating a stronger interfacial charge transfer capability at the ultrathin In 2 O 3 NSs/electrolyte interface.…”
Section: Spectral Photoresponse Of Ultrathin In 2 O 3 Nss Pec Pdsmentioning
confidence: 78%
“…In our previous works, we proposed an electrochemical (EC) etching method to detach GaN-based materials. , In this work, we detach the (In,Ga)N film from the original Si substrate by the EC method and transfer it to a flexible, conductive substrate. The flexible conductive substrate was obtained by sputtering indium–tin oxide (ITO) on a polyethylene terephthalate (PET) substrate.…”
Section: Introductionmentioning
confidence: 99%
“…By simulating biological neurons and synaptic functions, the artificial synaptic devices are the critical components for neuromorphic computing. In addition, flexible optoelectronic devices can be the indispensable parts of next-generation functional devices in the fields of flexible screens and wearable intelligent, etc [6][7][8][9]. Furthermore, flexible artificial synaptic devices with similar functions to the human brain can be widely used in various biomimetic fields, such as prosthetics, neurorobotics and health monitoring [4].…”
Section: Introductionmentioning
confidence: 99%