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Related Concept Videos

Biasing of FET01:22

Biasing of FET

256
Biasing a Junction Field Effect Transistor (JFET) is crucial for setting operational parameters and ensuring efficient functioning in electronic circuits. JFETs are characterized by using a single carrier type in N-channel or P-channel configurations, where the channel is surrounded by PN junctions. These junctions are central to the device's ability to control current flow.
In an N-channel JFET, the structure consists of N-type material forming the channel on a P-type substrate, with the...
256
Biasing of Metal-Semiconductor Junctions01:27

Biasing of Metal-Semiconductor Junctions

238
Biasing metal-semiconductor junctions involves applying a voltage across the junction. Specifically, the metal is connected to a voltage source, while the semiconductor is grounded. This technique is essential for controlling the direction and magnitude of current flow in electronic devices, including diodes, transistors, and photovoltaic cells.
In Schottky junctions, where the semiconductor is n-type, applying a positive voltage to the metal relative to the semiconductor reduces its Fermi...
238
MOSFET: Enhancement Mode01:22

MOSFET: Enhancement Mode

319
Enhancement-mode MOSFETs are pivotal components in electronics, distinguished by their capacity to act as highly efficient switches. They are part of the larger family of metal-oxide Semiconductor Field-Effect Transistors (MOSFETs). They are available in two types: p-channel and n-channel, each tailored to specific polarity operations.
In their basic form, enhancement-mode MOSFETs are typically non-conductive when the gate-source voltage (Vgs) is zero. This default 'off' state means no...
319
Small-Signal Analysis of MOSFET Amplifiers01:23

Small-Signal Analysis of MOSFET Amplifiers

542
In small-signal analysis, a MOSFET transistor amplifier acts as a linear amplifier when operating in its saturation region. The gate-to-source voltage (VGS) of the MOSFET is the sum of the DC biasing voltage and the small time-varying input signal. This combination sets up the operating point and modulates the drain current (ID) that flows from the drain to the source. When a small AC signal is superimposed on the DC bias voltage at the gate, the instantaneous drain current comprises three...
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MOSFET Amplifiers01:17

MOSFET Amplifiers

151
The MOSFET, when operating in its active region, functions as a voltage-controlled current source. In this region, the gate-to-source voltage controls the drain current. This principle underlies the operation of the transconductance MOSFET amplifier. The output current is directed through a load resistor to convert this amplifier into a voltage amplifier. The output voltage is then obtained by subtracting the voltage drop across the load resistance from the supply voltage. This process results...
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Biasing of P-N Junction01:16

Biasing of P-N Junction

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The operation of a p-n junction diode involves various biasing conditions, including forward bias, reverse bias, and equilibrium.
In equilibrium, no external voltage is applied across the p-n junction. The depletion region is formed at the junction interface due to the diffusion of carriers, which leaves behind charged dopants, acceptors on the p-side, and donors on the n-side. These immobile charges create an electric field that prevents further diffusion of carriers. The related energy band...
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Updated: Jun 21, 2025

Flow-assisted Dielectrophoresis: A Low Cost Method for the Fabrication of High Performance Solution-processable Nanowire Devices
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A mixer architecture using GaN-based split-gate nanowire transistor.

Jaya Jha1, Sreenadh Surapaneni1, Swaroop Ganguly1

  • 1Applied Quantum Mechanics Laboratory, Indian Institute of Technology Bombay, Powai, Mumbai 400076, India.

Nanotechnology
|July 16, 2024
PubMed
Summary
This summary is machine-generated.

This study introduces a novel Gallium Nitride (GaN) split-gate nanowire transistor mixer, achieving low conversion loss and high isolation for radio-frequency signal processing. This active device offers a promising alternative to traditional passive mixers.

Keywords:
AlGaN/GaNHEMTsconversion lossfrequency mixingisolationmixersplit-gate

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Area of Science:

  • Electrical Engineering
  • Materials Science
  • Radio-Frequency Engineering

Background:

  • Frequency mixers are crucial for radio-frequency (RF) signal processing, enabling frequency translation and phase comparison.
  • Traditional passive mixers exhibit significant conversion loss and poor isolation, limiting performance.
  • Active mixers, particularly on Gallium Nitride (GaN) technology, are less developed but offer potential advantages.

Purpose of the Study:

  • To demonstrate a novel mixer architecture utilizing a GaN split-gate nanowire transistor.
  • To achieve low conversion loss and high isolation in RF mixers.
  • To explore the potential of GaN technology for advanced monolithic mixer fabrication.

Main Methods:

  • Fabrication of a GaN split-gate nanowire transistor.
  • Utilizing electrostatic modulation of the effective gate width to form a constriction.
  • Experimental and theoretical verification of mixing characteristics, including S-parameter measurements.

Main Results:

  • The proposed GaN split-gate nanowire transistor mixer demonstrated low conversion loss.
  • Extremely high isolation was achieved, verified through three-port S-parameter measurements.
  • Output power spectral density peaked at the difference frequency, confirming effective frequency translation.

Conclusions:

  • The GaN split-gate nanowire transistor mixer offers a viable solution for low conversion loss and high isolation.
  • This architecture facilitates monolithic integration on the GaN platform, paving the way for advanced RF systems.
  • The demonstrated device represents a significant advancement in GaN-based active mixer technology.