Recent efforts in the field of organic photodetectors (OPD) have been focused on extending broadband detection into the near-infrared (NIR) region. Here, two blends of an ultralow bandgap push-pull polymer TQ-T combined with state-of-the-art non-fullerene acceptors, IEICO-4F and Y6, are compared to obtain OPDs for sensing in the NIR beyond 1100 nm, which is the cut off for benchmark Si photodiodes. It is observed that the TQ-T:IEICO-4F device has a superior IR responsivity (0.03 AW -1 at 1200 nm and -2 V bias) and can detect infrared light up to 1800 nm, while the TQ-T:Y6 blend shows a lower responsivity of 0.01 AW -1 . Device physics analyses are tied with spectroscopic and morphological studies to link the superior performance of TQ-T:IEICO-4F OPD to its faster charge separation as well as more favorable donor-acceptor domains mixing. In the polymer blend with Y6, the formation of large agglomerates that exceed the exciton diffusion length, which leads to high charge recombination, is observed. An application of these devices as biometric sensors for real-time heart rate monitoring via photoplethysmography, utilizing infrared light, is demonstrated.
One of the key challenges facing organic photodiodes (OPDs) is increasing the detection into the infrared region. Organic semiconductor polymers provide a platform for tuning the bandgap and optoelectronic response to go beyond the traditional 1000-nanometer benchmark. In this work, we present a near-infrared (NIR) polymer with absorption up to 1500 nanometers. The polymer-based OPD delivers a high specific detectivity
D
*
of 1.03 × 10
10
Jones (−2 volts) at 1200 nanometers and a dark current
J
d
of just 2.3 × 10
−6
ampere per square centimeter at −2 volts. We demonstrate a strong improvement of all OPD metrics in the NIR region compared to previously reported NIR OPD due to the enhanced crystallinity and optimized energy alignment, which leads to reduced charge recombination. The high
D
*
value in the 1100-to-1300-nanometer region is particularly promising for biosensing applications. We demonstrate the OPD as a pulse oximeter under NIR illumination, delivering heart rate and blood oxygen saturation readings in real time without signal amplification.
With the advent of nonfullerene acceptors (NFAs), organic
photovoltaic
(OPV) devices are now achieving high enough power conversion efficiencies
(PCEs) for commercialization. However, these high performances rely
on active layers processed from petroleum-based and toxic solvents,
which are undesirable for mass manufacturing. Here, we demonstrate
the use of biorenewable 2-methyltetrahydrofuran (2MeTHF) and cyclopentyl
methyl ether (CPME) solvents to process donor: NFA-based OPVs with
no additional additives in the active layer. Furthermore, to reduce
the overall carbon footprint of the manufacturing cycle of the OPVs,
we use polymeric donors that require a few synthetic steps for their
synthesis, namely, PTQ10 and FO6-T, which are blended with the Y-series
NFA Y12. High performance was achieved using 2MeTHF as the processing
solvent, reaching PCEs of 14.5% and 11.4% for PTQ10:Y12 and FO6-T:Y12
blends, respectively. This work demonstrates the potential of using
biorenewable solvents without additives for the processing of OPV
active layers, opening the door to large-scale and green manufacturing
of organic solar cells.
We report the first examples of carborane-containing non-fullerene acceptors (NFAs), and their use in organic photovoltaic (OPV) devices. NFAs employing an A-D-A’-D-A type design centred around a central electron withdrawing...
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