This article presents the raw and analyzed data from a set of experiments performed to study the role of junctions on the electrostatic gating of carbon nanotube (CNT) network field effect transistor (FET) aptasensors. It consists of the raw data used for the calculation of junction and bundle densities and describes the calculation of metallic content of the bundles. In addition, the data set consists of the electrical measurement data in a liquid gated environment for 119 different devices with four different CNT densities and summarizes their electrical properties. The data presented in this article are related to research article titled “Metallic-semiconducting junctions create sensing hot-spots in carbon nanotube FET aptasensors near percolation” (doi:10.1016/j.bios.2018.09.02110.1016/j.bios.2018.09.021) [1].
Colloidal
nanocrystals (NCs) are often described as solution processable
semiconductors. However, many state of the art devices use them in
the same manner as bulk semiconductors by fabricating conventional
device structures using vacuum deposition techniques. Here we show
that colloidal NCs can be deployed in an array of planar photodetectors
produced using a simple method of patterned spray coating to achieve
room-temperature detection of targets at 100 °C. HgTe nanocrystals
are synthesized with varying band gaps to produce arrays of multicolor
detectors operating in the mid-infrared (MIR). We demonstrate a 15-pixel
active imaging system that consists of a polymer substrate and up
to four 4-color pixels. The performance of these devices at room temperature
is enhanced by a low intensity photogain effect at 5 V bias that permits
a maximum EQE of 1900 ± 300% for a pixel with a 3.3 μm
bandgap. This device permits detection of an object only 75 °C
warmer than the detector in a noisy environment, acting as a proof
of concept for room-temperature NC devices that are able to image
objects at around 100 °C. We further show that the gain is sensitive
to the total incident flux and the device bias, suggesting a trap-assisted
mechanism. Finally, it is shown that solution patterned NC fabrication
methods can deliver adequate reproducibility between pixels to enable
production of an imaging plane of multiple pixels with a 15-pixel
device and deliver some degree of spatial resolution.
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