Light Detection in Open‐Circuit Voltage Mode of Organic Photodetectors

Kielar, Marcin; Hamid, Tasnuva; Wiemer, M.; Windels, François; Hirsch, Lionel; Sah, Pankaj; Pandey, Ajay K.

doi:10.1002/adfm.201907964

Cited by 42 publications

(42 citation statements)

References 48 publications

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“…Previously, we have shown that rubrene can efficiently function as an OPV and OLED with sub-bandgap turn-on voltage and able to detect ultralow light signals when combined with a suitable acceptor, such as fullerene-C 60 . [13,14,15] The origin of the multifunctional diode response of these chromophores has now been linked to arise due to the delicate interplay between singlet excitons, charge transfer states and triplet excitons. [16,17,18] This has led to research into a new class of organic optoelectronic devices, as opposed to their complete reliance on singlet excitons where the formation of triplet excitons has traditionally…”

Section: Multifunctional Diode Operation Of Tetracene Sensitized Polymentioning

confidence: 99%

Multifunctional Diode Operation of Tetracene Sensitized Polymer:Fullerene Heterojunctions with Simultaneous Electroluminescence in Visible and NIR Bands

Hamid

Kielar

Yambem

et al. 2020

Adv Elect Materials

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Multifunctional operation of tetracene/polycyclopentadithiophene‐benzothiadiazole (PCPDTBT), and tetracene sensitized PCPDTBT:fullerene bulk heterojunctions (BHJs) that work as an organic photovoltaic (OPV), organic light emitting diode (OLED), and organic photodetector (OPD) is unveiled. The multifunctional operation is underlined by a synergetic interplay between singlet and triplet energy transfer and the judicious alignment of energy levels of donor–acceptor cascade. Introduction of tetracene is shown to enhance electroluminescence (EL) at 800 nm despite the observation of a near‐complete photoluminescence quenching in BHJ systems. Signatures of triple energy transfer mediated via charge transfer states of BHJ to tetracene become apparent as the proportion of fullerene in the BHJ is increased. An optimal balance between exciton population is achieved with BHJ 1:2 that produces EL peaks at 530 and 800 nm while maintaining a respectable OPV and OPD performance. The proposed ternary system unlocks the potential of having multifunctionality within one single diode structure, and it also offers new design rules for multispectral OLEDs.

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Section: Multifunctional Diode Operation Of Tetracene Sensitized Polymentioning

confidence: 99%

Multifunctional Diode Operation of Tetracene Sensitized Polymer:Fullerene Heterojunctions with Simultaneous Electroluminescence in Visible and NIR Bands

Hamid

Kielar

Yambem

et al. 2020

Adv Elect Materials

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“…Organic materials have attracted tremendous attention due to various advantages such as their low manufacturing costs, low-temperature processability, intrinsic mechanical flexibility, and diversified band gap selection through molecular design. , Organic single crystals present highly ordered molecular packing, absence of grain boundaries, and extremely low defect density, which make them an ideal platform for both the fundamental research and potential applications. Rubrene is a typical organic semiconductor with a herringbone packing arrangement and has been widely exploited in high-performance field-effect transistors, , flexible strain sensors, and phototransistor memories, , due to its high carrier mobility, intrinsic mechanical flexibility, and excellent absorption .…”

Section: Introductionmentioning

confidence: 99%

Highly Sensitive and Ultrafast Organic Phototransistor Based on Rubrene Single Crystals

Qin

Wang

et al. 2021

ACS Appl. Mater. Interfaces

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Rubrene single crystals have received a lot of attention for their great potential in electronic and wearable nanoelectronics due to their high carrier mobility and excellent flexibility. While they exhibited remarkable electrical performances, their intrinsic potential as photon detectors has not been fully exploited. Here, we fabricate a sensitive and ultrafast organic phototransistor based on rubrene single crystals. The device covers the ultraviolet to visible range (275–532 nm), and the responsivity and detectivity can reach up to ∼4000 A W–1 and 1011 jones at 532 nm, respectively. Furthermore, the response times are highly gate-tunable down to sub-90 μs, and the cutoff frequency is ∼4 kHz, which is one of the fastest organic material-based phototransistors reported so far. Equally important is that the fabricated device exhibits stable light detection ability even after 8 months, indicating great long-term stability and excellent environmental robustness. The results suggest that the high-quality rubrene single crystal may be a promising material for future flexible optoelectronics with its intrinsic mechanical flexibility.

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“…The rise time (t r ) and fall time (t f ) of transient photocurrent are defined as the time for photocurrent raising from 10% to 90% of the maximum photocurrent and the time for photocurrent decreasing from 90% to 10% of the maximum photocurrent. [36] The t r and t f of PM-PPDs with F 6 TCNNQ in active layers are estimated to be 16.3 and 56.7 ms, respectively, which are shorter than the corresponding values of 27.7 and 85 ms for PM-PPDs without F 6 TCNNQ in active layers. The increased response speed of PM-PPDs with F 6 TCNNQ in active layers should be due to the enhanced hole mobility.…”

Section: Resultsmentioning

confidence: 77%

Efficient p‐Doping with F₆TCNNQ for Improving Performance of Polymer Photodetectors with Photomultiplication

Wang

Yin

et al. 2021

Physica Rapid Research Ltrs

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Polymer photodetectors with photomultiplication (PM-PPDs) are prepared with PC 71 BM:P3HT (1:100, wt/wt) active layers containing efficient hole-transport channels and large amount of isolated electron traps. The solid additive F 6 TCNNQ is incorporated into PC 71 BM:P3HT blend films with rather low content of 0.02 wt%. The external quantum efficiency (EQE) and response speed of PM-PPDs with F 6 TCNNQ additive in the active layer are much larger than those of PM-PPDs without F 6 TCNNQ additive under the same bias. The EQE values at 400 and 625 nm can reach 5240% and 3050% for the PM-PPDs with F 6 TCNNQ in active layers under À9 V bias, which is among the highest values for PM-PPDs under the same bias. The performance improvement of PM-PPDs with F 6 TCNNQ is primarily ascribed to the enhanced hole mobility in the active layer, leading to the increased response speed with rise time of 27.7 ms and fall time of 85 ms. This work indicates that performance of PM-PPDs can be markedly enhanced by using p-doping with strong oxidizing agents, beneficial for an enhancement in hole mobility in F 6 TCNNQ:PC 71 BM:P3HT active layers.

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Light Detection in Open‐Circuit Voltage Mode of Organic Photodetectors

Cited by 42 publications

References 48 publications

Multifunctional Diode Operation of Tetracene Sensitized Polymer:Fullerene Heterojunctions with Simultaneous Electroluminescence in Visible and NIR Bands

Multifunctional Diode Operation of Tetracene Sensitized Polymer:Fullerene Heterojunctions with Simultaneous Electroluminescence in Visible and NIR Bands

Highly Sensitive and Ultrafast Organic Phototransistor Based on Rubrene Single Crystals

Efficient p‐Doping with F₆TCNNQ for Improving Performance of Polymer Photodetectors with Photomultiplication

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Light Detection in Open‐Circuit Voltage Mode of Organic Photodetectors

Cited by 42 publications

References 48 publications

Multifunctional Diode Operation of Tetracene Sensitized Polymer:Fullerene Heterojunctions with Simultaneous Electroluminescence in Visible and NIR Bands

Multifunctional Diode Operation of Tetracene Sensitized Polymer:Fullerene Heterojunctions with Simultaneous Electroluminescence in Visible and NIR Bands

Highly Sensitive and Ultrafast Organic Phototransistor Based on Rubrene Single Crystals

Efficient p‐Doping with F6TCNNQ for Improving Performance of Polymer Photodetectors with Photomultiplication

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Efficient p‐Doping with F₆TCNNQ for Improving Performance of Polymer Photodetectors with Photomultiplication