Dark Current Reduction Strategy via a Layer-By-Layer Solution Process for a High-Performance All-Polymer Photodetector

Zhong, Zhou; Bu, Laju; Zhu, Peng; Tong, Xiao; Fan, Baobing; Ying, Lei; Lu, Guanghao; Yu, Gang; Huang, Fei; Cao, Yong

doi:10.1021/acsami.8b20981

Cited by 80 publications

(81 citation statements)

References 42 publications

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“…Therefore, it is not reasonable to utilize Equation (1) for estimating D*. Besides, we observed similar behavior of polymer photodetectors in other works, [51,55] implying that the equation for D* should be used as following [51,[53][54][55]…”

Section: Resultsmentioning

confidence: 71%

“…Specific detectivity, D*, of a photodetector determines its ability to detect the weakest photosignal under various noises such as shot, Johnson (thermal), and flicker (1/f). [12,19,22,[49][50][51][52][53][54] D* is a crucial figure of merit for photodetectors, which is usually expressed in the simple equation by [8][9][10][11][12][13][14][15][16][17][18]21,22,38,52,54,55]…”

Section: Resultsmentioning

confidence: 99%

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Vacuum‐Processed Small Molecule Organic Photodetectors with Low Dark Current Density and Strong Response to Near‐Infrared Wavelength

Lee

Estrada

et al. 2020

Advanced Optical Materials

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A near‐infrared photodetector with optimized performance is reported using varied thickness (20, 40, 60, and 80 nm) of the active layer comprising chloroaluminium phthalocyanine (ClAlPc) and fullerene (C70) at the ratio of 1:3, and TAPC:10% MoO3 and BPhen as electron and hole blocking layers, respectively. The experimental results reveal that the photodetector with 80 nm thick active layer provides the best performance at the wavelength of 730 nm achieving a very low dark current density of 1.15 × 10−9 A cm−2 and an external quantum efficiency of 74.6% with a responsivity of 0.439 A W−1 at −2 V bias. Additionally, the device exhibits a dramatic high detectivity of 4.14 × 1013 cm Hz1/2 W−1 at 0 V bias. The device exhibits not only a large linear response over a wide optical power range (LDR of 173.0 dB), but also a broad frequency response (778.7 kHz) and rise/fall time of 2.13/0.77 µs (based on trigger pulses at a frequency of 10 kHz) at the applied bias of −2 V. Based on the impedance spectroscopic study and the conventional characterization of electro‐optical properties, the results demonstrate the superiority of this device over other small molecule‐based near‐infrared photodetectors.

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Section: Resultsmentioning

confidence: 71%

Section: Resultsmentioning

confidence: 99%

Vacuum‐Processed Small Molecule Organic Photodetectors with Low Dark Current Density and Strong Response to Near‐Infrared Wavelength

Lee

Estrada

et al. 2020

Advanced Optical Materials

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“…This could be true when dark current is high (cases under reverse bias). Due to the difficulty of measuring the real noise, only quite a few papers24,31–34 have measured rather than estimated the noise. In these measurements, the noise was in fact far beyond shot noise limit and showing domination of 1/ f n noise ( n ≥ 1), which decreases dramatically with increasing frequency but sometimes can still be higher than shot noise even at 1 kHz.…”

Section: Resultsmentioning

confidence: 99%

All‐Polymer High‐Performance Photodetector through Lamination

Xia

Aguirre

et al. 2020

Adv Elect Materials

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All‐polymer and semitransparent organic photodetectors (OPDs) fabricated through lamination on flexible substrates are demonstrated. Through lamination both bilayer and bulk heterojunction (BHJ) configurations for two different all‐polymer blends are easily made, and characterized in terms of detectivity, linear dynamic range (LDR), and bandwidth. These devices show high detectivity up to 1011 Jones. The importance of measured noise rather than estimated shot noise in detectivity calculation is discussed and emphasized. With this high detectivity and with the geometric flexibility due to the polymer materials, these detectors can be attached to curved surfaces for optical detection. Their use at fingertips for heart rate sensing is demonstrated. These devices also have a very wide bandwidth of more than 300 kHz and an LDR of 75 dB. As such the, roll‐to‐roll compatible lamination method shows great potential for high‐performance OPDs fabrication.

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“…not universally adopted, but instead many reports estimate D* based on only the shot noise and/or the thermal noise. [67] This simplification may lead to significant overestimation of the actual detectivity, [65,68] and makes it difficult to compare the performance of devices reported by different research groups.…”

Section: Noise Equivalent Power (Nep) and Specific Detectivity (D*)mentioning

confidence: 99%

“…Recently, Zhong et al reduced the dark (noise) current by using a layerbylayer (LBL) solution processing method. [68] As opposed to the conventional onestep solution method, where the donor and acceptor are processed from the same solution, the LBL approach first deposits the donor before processing the acceptor layer (Figure 3f-h). Although this is similar to how conventional planar heterojunction are made, in this case the donor and acceptor layers are not completely separated but instead they are able to partially mix in order to form BHJ mor phology while maintaining vertical segregation.…”

Section: Dark and Noise Current Reductionmentioning

confidence: 99%

Organic Photodetectors for Next‐Generation Wearable Electronics

2019

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The ORCID identification number(s) for the author(s) of this article can be found under https://doi.org/10.1002/adma.201902045.Next-generation wearable electronics will need to be mechanically flexible and stretchable such that they can be conformally attached onto the human body. Photodetectors that are available in today's market are based on rigid inorganic crystalline materials and they have limited mechanical flexibility. In contrast, photodetectors based on organic polymers and molecules have emerged as promising alternatives due to their inherent mechanical softness, ease of processing, tunable optoelectronic properties, good light sensing performance, and biocompatibility. Here, the recent advances of organic photodetectors in terms of both optoelectronic and mechanical properties are outlined and discussed, and their application in wearable electronics including health monitoring sensors, artificial vision, and self-powering integrated devices are highlighted.

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Dark Current Reduction Strategy via a Layer-By-Layer Solution Process for a High-Performance All-Polymer Photodetector

Cited by 80 publications

References 42 publications

Vacuum‐Processed Small Molecule Organic Photodetectors with Low Dark Current Density and Strong Response to Near‐Infrared Wavelength

Vacuum‐Processed Small Molecule Organic Photodetectors with Low Dark Current Density and Strong Response to Near‐Infrared Wavelength

All‐Polymer High‐Performance Photodetector through Lamination

Organic Photodetectors for Next‐Generation Wearable Electronics

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