Toward Unusual‐High Hole Mobility of p‐Channel Field‐Effect‐Transistors

Chen

ACS Appl. Mater. Interfaces

et al. 2022

Self Cite

Realizing omnidirectional self-powered photodetectors is central to advancing next-generation portable and smart photodetector systems. However, the traditional omnidirectional photodetector is typically achieved by integrating complex hemispherical microlens on multiple photodetectors, which makes the detection system cumbersome and restricts its application in the portable field. Here, facile and high-performance flexible omnidirectional self-powered photodetectors are achieved by solution-processed two-dimensional (2D) layered PbI2 nanoplates on transparent conducting substrates. Characterization of PbI2 nanoplates microstructural/compositional and their photodetection properties have been systematically characterized. Under the irradiation of a 405 nm laser, the photodetectors exhibit an impressively low dark current of 10–13 A, a high light on/off ratio up to 106, and a fast rise/decay response time of 2/3 ms. Importantly, when light irradiates the photodetector at 5°, it can still maintain high photodetection properties, realizing almost 360° omnidirectional self-powered photodetection. What is more, these self-powered photodetectors exhibit robust omnidirectional photoresponse stability of flexibility even after bending for 1200 cycles. Thus, this work broadens the applicability of 2D layered nanoplates for further extending its applications in advanced optoelectronic devices.

Section: Resultssupporting

confidence: 79%

Flexible Omnidirectional Self-Powered Photodetectors Enabled by Solution-Processed Two-Dimensional Layered PbI₂ Nanoplates

Chen

ACS Appl. Mater. Interfaces

et al. 2022

Self Cite

“…GaSb NWs are technologically important narrow-bandgap III–V semiconductors ascribed to the physical properties of direct bandgap (∼0.726 eV), zinc blende structure, p-type conductivity, and high hole mobility. They have been explored to build high-performance field-effect transistors (FETs) and near-infrared photodetectors. − Because of the intrinsic light polarization sensitivity, GaSb NWs are also good candidates for near-infrared polarization photodetectors. , Nonetheless, it is still challenging to realize the application of GaSb NW-based photodetectors because of their excessive dark current and the deteriorated surface oxidation, which are also common problems of other III–V semiconductor devices. − The excessive dark current will result in large device noise, and the deteriorated surface oxidation will trap photogenerated carriers, thus downgrading the photoelectric performance of GaSb NWs-based photodetctors. , Recently, the reported sulfur-catalyzed growth of GaSb NWs was found to be an effective way to resolve these problems. Compared with pure GaSb NWs, the obtained sulfur-passivation GaSb NWs have thinner diameters, and the S is not doped into the NW core but distributed on the surface. ,, For instance, in the report of Wang et al, the S-catalyzed chemical vapor deposition (CVD) method was used to grow GaAs x Sb 1– x NWs with Sb x S y and Ga x S y layers being formed on the NWs surface.…”

mentioning

confidence: 99%

Near-Infrared Polarimetric Image Sensors Based on Ordered Sulfur-Passivation GaSb Nanowire Arrays

et al. 2022

Self Cite

The near-infrared polarimetric image sensor has a wide range of applications in the military and civilian fields, thus developing into a research hotspot in recent years. Because of their distinguishing 1D structure features, the ordered GaSb nanowire (NW) arrays possess potential applications for near-infrared polarization photodetection. In this work, single-crystalline GaSb NWs are synthesized through a sulfur-catalyzed chemical vapor deposition process. A sulfur-passivation thin layer is formed on the NW surface, which prevents the GaSb NW core from being oxidized. The photodetector based on sulfur-passivation GaSb (S-GaSb) NWs has a lower dark current and higher responsivity than that built with pure GaSb NWs. The photodetector exhibits a large responsivity of 9.39 × 102 A/W and an ultrahigh detectivity of 1.10 × 1011 Jones for 1.55 μm incident light. Furthermore, the dichroic ratio of the device is measured to reach 2.65 for polarized 1.55 μm light. Through a COMSOL simulation, it is elucidated that the origin of the polarized photoresponse is the attenuation of a light electric field inside the NW when the angle of incident polarization light rotates. Moreover, a flexible polarimetric image sensor with 5 × 5 pixels is successfully constructed on the ordered S-GaSb NW arrays, and it exhibits a good imaging ability for incident near-infrared polarization light. These good photoresponse properties and polarized imaging abilities can empower ordered S-GaSb NW arrays with technological potentials in next-generation large-scale near-infrared polarimetric imaging sensors.

“…The determining factor for μ is scattering effect. [ 28 ] The schematic of the modified a‐IGZO layer and of its resistance during the carrier transport process are shown in Figure S6 (Supporting Information) to prove scattering change. For the post‐treated 41‐nm device, at the on state, the carriers go into the layer with many defects after going through the modified layer with few defects at high speed.…”

Section: Resultsmentioning

confidence: 99%

Analysis of Carrier Behavior for Amorphous Indium Gallium Zinc Oxide After Supercritical Carbon Dioxide Treatment

Zhang

Chang

et al. 2022

Adv Materials Inter

Researchers have made various attempts to improve the sputtering a-IGZO films. [2] However, the structural defects induced by the sputtering process often lead to inferior performance and stability for a-IGZO devices, especially under voltage stress. [9] Poor-quality of a-IGZO film has hindered the development of commercial applications for a-IGZO thin film transistor (TFT)based electronics. [10][11][12] Many post-treatments such as annealing, [13] microwave irradiation, [14] plasma treatment, [15][16][17] and supercritical carbon dioxide fluid (SCCO 2 ) treatment [18,19] have been implemented to improve a-IGZO film quality. Compared with other methods, SCCO 2 method is more promising due to its low-temperature process, nondestructive property, ability to remove organic impurities, and restorability from bending. Earlier work [18] has studied the enhancing effect of this treatment on flexible a-IGZO devices. To gain maximum advantage of such technique, an understanding of the carrier mechanism beyond the performance enhancement is important. From oxygen vacancy (V o ) theory, two kinds of V o could exist in the a-IGZO film, namely traps and carriers. [20] The independent analysis for carrier-type V o and trap-type V o has not been verified in detail. Furthermore, the carrier transport mechanism of the post-treated a-IGZO film has not been fully understood yet. These are critical to understand the a-IGZO and realize high-performance devices and circuits based on metal oxide semiconductors.In this work, we design a-IGZO TFTs with different channel thicknesses and treat them using SCCO 2 process to investigate the detailed mechanism of the carrier behavior inside the a-IGZO layer. By comparing the performances of different devices, we analyze the carrier density and transport in a-IGZO. In addition to the traditional X-ray photoelectron spectroscopy (XPS) and Fourier transform infrared spectroscopy (FTIR) characterization, new techniques including Technology Computer Aided Design (TCAD) simulation, layer-by-layer XPS, and sheet resistance measurement are adopted in TFTs for the first time to verify the more accurate carrier mechanism.Amorphous indium gallium zinc oxide (a-IGZO) thin-film quality can be enhanced using supercritical carbon dioxide (SCCO 2 ). How to verify specific and accurate mechanism for the carriers inside an a-IGZO layer before and after the SCCO 2 treatment is worth investigating. This work designs a-IGZO thin film transistors with different channel thicknesses (41, 28, and 19 nm), treats them using SCCO 2 , and analyzes the change in carrier behavior. The effect of the SCCO 2 on both carrier density and carrier transport is investigated using energy band information, Technology Computer Aided Design (TCAD) simulations on density of states and resistance analyses. After the treatment, the thinner channel thickness exhibits better drivability enhancement. That is because of the fewer traps and smoother carrier transportation path resulted from better M−O−M frameworks, and decreased M−OH bonds as ...