Stacked Dual‐Wavelength Near‐Infrared Organic Photodetectors

Wang, Yazhong; Siegmund, Bernhard; Tang, Zheng; Ma, Zaifei; Kublitski, Jonas; Xing, Shen; Nikolis, Vasileios C.; Ullbrich, Sascha; Li, Yungui; Benduhn, Johannes; Spoltore, Donato; Vandewal, Koen; Leo, Karl

doi:10.1002/adom.202001784

Cited by 47 publications

(47 citation statements)

References 31 publications

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“…The EQE at 660 nm of PMOPDs is about 760% under an applied voltage of −20 V. When the OFA layer thick ness is increased to 3.5 µm, the response peak is redshifted to 675 nm, and the corresponding EQE value is about 370% under an applied voltage of −20 V. To clarify the effect of OFA layer thickness on the performance of PMOPDs, optical distribu tion was investigated based on the device structure of ITO/ PEDOT:PSS/P3HT (3.5 µm)/P3HT:PC 71 BM (50 nm)/Al by employing the transfer matrix method. [33,34] The optical field distribution in the PMOPDs with 3.5 µm OFA layer and 50 nm PM layer is exhibited in Figure 3a. It is obvious that the incident photon with a wavelength of <670 nm can be completely harvested in the 3.5 µm thick OFA layer.…”

Section: Resultsmentioning

confidence: 99%

Highly Sensitive Narrowband Photomultiplication‐Type Organic Photodetectors Prepared by Transfer‐Printed Technology

Zhao

Liu

Yang

et al. 2021

Adv Funct Materials

120

113

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Narrowband photomultiplication-type organic photodetectors (PMOPDs) are realized with poly(3-hexylthiophene-2,5-diyl) (P3HT) as the optical field adjusting (OFA) layer and transfer-printed P3HT: [6,6]-phenyl-C 71 -butyric acid methyl ester (PC 71 BM) (50:1, w/w) as the photomultiplication (PM) layer. The thickness of the OFA layers is adjusted to optimize interfacial trapped electron distribution and density, which determines the external quantum efficiency (EQE) and spectral response range of PMOPDs. Narrowband PMOPDs with 2.5 µm thick P3HT as the OFA layer exhibit two narrow response peaks at 350 and 660 nm, and the corresponding EQE values at 350 and 660 nm are 180% and 760% under an applied bias of −20 V. A wide bandgap polymer poly[N,N′-bis(4-butylphenyl)-N,N′-bis(phenyl)benzidine] (P-TPD) is deliberately incorporated into OFA layer for adjusting interfacial trapped electron distribution near Al electrode. Narrowband PMOPDs exhibit only one response peak at 660 nm with the enhanced EQE value of 1120% under the same bias. The enhanced EQE of PMOPDs with P-TPD is primarily attributed to the increased hole tunneling injection and transport, which can be ascribed to the enhanced trapped electron density near the Al electrode and the improved hole mobility, respectively. Clearly resolved images can be obtained from the imaging system with the narrowband PMOPDs as sensing pixel without any current preamplifier, indicating the promising potential of PMOPDs in imaging sense.

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Section: Resultsmentioning

confidence: 99%

Highly Sensitive Narrowband Photomultiplication‐Type Organic Photodetectors Prepared by Transfer‐Printed Technology

Zhao

Liu

Yang

et al. 2021

Adv Funct Materials

120

113

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“…Single-wavelength mode Physics of microcavities. In general, the intrinsic absorption coefficient (a) at peak wavelength of typical photo-absorbing materials is around 10 5 cm À1 , 82,85,194 which gives an absorption attenuation length of around 50 nm. Therefore, in normal organic electronic devices, such as OSCs, the needed photoabsorbing layer thicknesses are several tens to one hundred nanometers to achieve as high as possible absorption.…”

Section: Microcavity Enhanced Narrowband Opdsmentioning

confidence: 99%

“…79 In 2017, tunable narrowband OPDs with BHJ embedded into Fabry-Pe ´rot microcavities 80 were accomplished, with single or dual wavelengths detection capabilities. 27,74,81,82 In 2020, Xing et al introduced self-filtering narrowband OPDs composed of a depletion layer, a donor and a thin acceptor layer, forming a planar heterojunction (PHJ). 83 Tunable red and NIR narrowband OPDs were achieved.…”

Section: Introduction Of Broadband and Narrowband Opdsmentioning

confidence: 99%

Narrowband organic photodetectors – towards miniaturized, spectroscopic sensing

et al. 2022

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“…Figure shows D * values extracted from 43 papers reporting narrow‐band OPDs from the year 2012 onwards with an FWHM value of a maximum of 150 nm. [ 4,17–21,25,28,30–34,38–67 ] To get an overview of the current status of the field, it is instructive to plot D * as a function of peak EQE value, J d , and design wavelength. It is important to mention that not in all of these papers the noise currents have been directly measured and D * has often been calculated using

i_{noise}^{\min}

, given by Equation (2).…”

Section: Important Figures Of Merit and Limitations Of Organic Photodetectorsmentioning

confidence: 99%

Wavelength‐Selective Organic Photodetectors

Vanderspikken

Maes

Vandewal

2021

Adv Funct Materials

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Spectroscopic sensing combined with optical imaging is crucial with respect to today's ever‐growing demand for instant analytical techniques to be incorporated in various handheld and wearable devices. Further miniaturization and integration of such types of sensors is critical and wavelength‐selective organic photodetectors (OPDs) may provide the required technology. In this progress report, some early OPD applications and their potential are presented. Crucial device parameters such as the specific detectivity, external quantum efficiency, and dark current density of visible and near‐infrared wavelength‐selective photodetectors are compared and assayed to theoretical and semi‐empirical limits. The different organic detector approaches include the use of inherently narrow‐band absorbers as well as internally filtered and microcavity devices. Each of these strategies comes with its own specific material and device design criteria, around which material development and selection should be centered to move beyond the current state of the art. As OPD technology matures, device stability becomes important and is hence also briefly discussed. Via this perspective, it is aimed to provide the reader with critical insights into the device physics and chemistry of wavelength‐selective OPDs, hereby providing leverage for new ideas to bring this technology to the market.

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Stacked Dual‐Wavelength Near‐Infrared Organic Photodetectors

Cited by 47 publications

References 31 publications

Highly Sensitive Narrowband Photomultiplication‐Type Organic Photodetectors Prepared by Transfer‐Printed Technology

Highly Sensitive Narrowband Photomultiplication‐Type Organic Photodetectors Prepared by Transfer‐Printed Technology

Narrowband organic photodetectors – towards miniaturized, spectroscopic sensing

Wavelength‐Selective Organic Photodetectors

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