It is often suggested that the dark leakage current of organic photodiodes is due to extrinsic leakage paths that do not involve the electronic junction. By studying a series of devices, where the acceptor is kept constant (C70) and the donor material is varied, we find a direct correlation between the strength of the sub-gap signature of the charge-transfer states and the leakage current. Attributing the differences in the sub-gap absorption to the donor's sub-gap states suggests that the donor's side of the junction should be made longer, to push the Fermi level at V = 0 towards the acceptor's LUMO, and thus, an optimized value of 800 Pacm−2 at V = −1 V is reported.
The anisotropic growth of gold nanoparticles under the influence of gemini surfactants is studied. The growth mechanism is discussed using electronic structure calculation modeling.
Organic photodiodes (OPDs) for its interesting optoelectronic properties has the potential to be utilized with complementary metal-oxide-semiconductor (CMOS) circuit for imaging, automotive, and security based applications. To achieve such a hybrid device as an image sensor, it is imperative that the quality of the OPD remains high on the CMOS substrate and that it has a well-connected optoelectronic interface with the underneath readout integrated circuit (ROIC) for efficient photogeneration and signal readout. Here, we demonstrate seamless integration of a thermally deposited visible light sensitive small molecule OPD on a standard commercial CMOS substrate using optimized doped PCBM buffer layer. Under a standard power supply voltage of 3 V, this hybrid device shows an excellent photolinearity in the entire bias regime, a high pixel sensitivity of 2 V/Lux.sec, a dynamic range (DR) of 71 dB, and a low dark leakage current density of 1 nA/cm2. Moreover, the integrated OPD has a minimum bandwidth of 400 kHz. The photoresponse nonuniformity being only 1.7%, achieved under research lab conditions, strengthens the notion that this fully-CMOS compatible technology has the potential to be applied in high-performance large-scale imaging array.
We report an optoelectronic
device consisting of a solution-processed indium gallium zinc oxide
(IGZO) thin-film transistor and vacuum-deposited small organic molecules.
Depending on the configurations of the organic materials, either bulk
heterojunction or planar heterojunction (PHJ), the device assumes
the functionality of either a photosensor or a photoinduced memory,
respectively. Under λ = 625 nm light illumination, the photosensor
shows response and recovery time of ∼50 ms, responsivity of
∼5 mA/W, sensitivity above 10
4
, and a linear response.
The mechanism of the photoinduced memory is studied experimentally
and verified using a device simulation. We find that the memory is
due to long charge retention time at the organic PHJ interface which
is stable for over 9 days. It is correlated with the low leakage current
found in ordered organic junctions having low subgap tail states.
The presented integration of the PHJ with the transistor constitutes
a new design of write-once-read-many-times memory device that is likely
to be attractive for low-cost applications.
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