Low effective mass and carrier concentration optimization for high performance p-type Mg2(1−x)Li2xSi0.3Sn0.7solid solutions

In this study, the ZnTe thin films were deposited on a glass substrate at a thickness of 400nm using vacuum evaporation technique (2×10-5mbar) at RT. Electrical conductivity and Hall effect measurements have been investigated as a function of variation of the doping ratios (3,5,7%) of the Cu element on the thin ZnTe films. The temperature range of (25-200°C) is to record the electrical conductivity values. The results of the films have two types of transport mechanisms of free carriers with two values of activation energy (Ea1, Ea2), expect 3% Cu. The activation energy (Ea1) increased from 29meV to 157meV before and after doping (Cu at 5%) respectively. The results of Hall effect measurements of ZnTe , ZnTe:Cu films show that all films were (p-type), the carrier concentration (1.1×1020 m-3) , Hall mobility (0.464m2/V.s) for pure ZnTe film, increases the carrier concentration (6.3×1021m-3) Hall mobility (2m2/V.s) for doping (Cu at 3%) film, but decreases by increasing Cu concentration.

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High performance 0.25 [micro sign]m p-type Ge/SiGe MODFETs

Electronics Letters ◽

10.1049/el:19981284 ◽

1998 ◽

Vol 34 (19) ◽

pp. 1888 ◽

Cited By ~ 45

Author(s):

G. Höck ◽

T. Hackbarth ◽

U. Erben ◽

E. Kohn ◽

U. König

Keyword(s):

High Performance ◽

P Type

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P-type Co3O4 nanoarrays decorated on the surface of n-type flower-like WO3 nanosheets for high-performance gas sensing

Sensors and Actuators B Chemical ◽

10.1016/j.snb.2019.02.101 ◽

2019 ◽

Vol 288 ◽

pp. 104-112 ◽

Cited By ~ 12

Author(s):

Yanghai Gui ◽

Lele Yang ◽

Kuan Tian ◽

Hongzhong Zhang ◽

Shaoming Fang

Keyword(s):

High Performance ◽

Gas Sensing ◽

P Type ◽

Co3o4 Nanoarrays

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Nanonet: Low-temperature-processed tellurium nanowire network for scalable p-type field-effect transistors and a highly sensitive phototransistor array

NPG Asia Materials ◽

10.1038/s41427-021-00314-y ◽

2021 ◽

Vol 13 (1) ◽

Author(s):

Muhammad Naqi ◽

Kyung Hwan Choi ◽

Hocheon Yoo ◽

Sudong Chae ◽

Bum Jun Kim ◽

...

Keyword(s):

Low Temperature ◽

Field Effect ◽

High Performance ◽

Field Effect Transistors ◽

Optical Measurements ◽

Electrical Performance ◽

Large Area ◽

Nanowire Network ◽

P Type ◽

Nanowire Networks

AbstractLow-temperature-processed semiconductors are an emerging need for next-generation scalable electronics, and these semiconductors need to feature large-area fabrication, solution processability, high electrical performance, and wide spectral optical absorption properties. Although various strategies of low-temperature-processed n-type semiconductors have been achieved, the development of high-performance p-type semiconductors at low temperature is still limited. Here, we report a unique low-temperature-processed method to synthesize tellurium nanowire networks (Te-nanonets) over a scalable area for the fabrication of high-performance large-area p-type field-effect transistors (FETs) with uniform and stable electrical and optical properties. Maximum mobility of 4.7 cm2/Vs, an on/off current ratio of 1 × 104, and a maximum transconductance of 2.18 µS are achieved. To further demonstrate the applicability of the proposed semiconductor, the electrical performance of a Te-nanonet-based transistor array of 42 devices is also measured, revealing stable and uniform results. Finally, to broaden the applicability of p-type Te-nanonet-based FETs, optical measurements are demonstrated over a wide spectral range, revealing an exceptionally uniform optical performance.

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2,2'-(Arylenedivinylene)bis-8-hydroxyquinolines exhibiting aromatic π-π stacking interactions as solution-processable p-type organic semiconductors for high-performance organic field effect transistors

Materials Advances ◽

10.1039/d1ma00215e ◽

2021 ◽

Author(s):

Suman Yadav ◽

Shivani Sharma ◽

Satinder K Sharma ◽

Chullikkattil P. Pradeep

Keyword(s):

Organic Semiconductors ◽

Field Effect ◽

High Performance ◽

Field Effect Transistor ◽

Field Effect Transistors ◽

Organic Field Effect Transistors ◽

Organic Thin Film ◽

Effect Transistor ◽

Solution Processable ◽

P Type

Solution-processable organic semiconductors capable of functioning at low operating voltages (~5 V) are in demand for organic field-effect transistor (OFET) applications. Exploration of new classes of compounds as organic thin-film...

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Demonstration of a Robust All-Silicon-Carbide Intracortical Neural Interface

Micromachines ◽

10.3390/mi9080412 ◽

2018 ◽

Vol 9 (8) ◽

pp. 412 ◽

Cited By ~ 9

Author(s):

Evans Bernardin ◽

Christopher Frewin ◽

Richard Everly ◽

Jawad Ul Hassan ◽

Stephen Saddow

Keyword(s):

Silicon Carbide ◽

High Performance ◽

Electrical Characterization ◽

Electrode Impedance ◽

Voltage Range ◽

Promising Solution ◽

Multiple Materials ◽

Diode Behavior ◽

Materials Used ◽

P Type

Intracortical neural interfaces (INI) have made impressive progress in recent years but still display questionable long-term reliability. Here, we report on the development and characterization of highly resilient monolithic silicon carbide (SiC) neural devices. SiC is a physically robust, biocompatible, and chemically inert semiconductor. The device support was micromachined from p-type SiC with conductors created from n-type SiC, simultaneously providing electrical isolation through the resulting p-n junction. Electrodes possessed geometric surface area (GSA) varying from 496 to 500 K μm2. Electrical characterization showed high-performance p-n diode behavior, with typical turn-on voltages of ~2.3 V and reverse bias leakage below 1 nArms. Current leakage between adjacent electrodes was ~7.5 nArms over a voltage range of −50 V to 50 V. The devices interacted electrochemically with a purely capacitive relationship at frequencies less than 10 kHz. Electrode impedance ranged from 675 ± 130 kΩ (GSA = 496 µm2) to 46.5 ± 4.80 kΩ (GSA = 500 K µm2). Since the all-SiC devices rely on the integration of only robust and highly compatible SiC material, they offer a promising solution to probe delamination and biological rejection associated with the use of multiple materials used in many current INI devices.

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