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Related Concept Videos

Field Effect Transistor01:29

Field Effect Transistor

706
Field-effect transistors (FETs) are integral to electronic circuits and distinguished by their three-terminal setup: the gate, drain, and source. These transistors operate as unipolar devices, which utilize either electrons or holes as charge carriers, in contrast to bipolar transistors, which use both types of carriers. The primary function of the FET is to modulate the flow of these carriers from the source to the drain through a channel. The voltage difference between the gate and source...
706
MOSFET: Enhancement Mode01:22

MOSFET: Enhancement Mode

531
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...
531
MOSFET: Depletion Mode01:20

MOSFET: Depletion Mode

532
Depletion-mode MOSFETs represent a unique subset of MOSFET technology, functioning fundamentally differently from their enhancement-mode counterparts. Unlike enhancement MOSFETs, which require a positive gate-source voltage (Vgs) to turn on, depletion-mode MOSFETs are inherently conductive and "normally on" devices.
The primary characteristic of depletion-mode MOSFETs is their ability to conduct current between the drain and source terminals without gate bias. This inherent conductivity...
532
MOSFET01:16

MOSFET

700
The Metal-Oxide-Semiconductor Field-Effect Transistor (MOSFET) plays a pivotal role in modern electronics thanks to its versatility and efficiency in controlling electrical currents. This device, also known as IGFET, MISFET, and MOSFET, has three main terminals: the Source, Drain, and Gate. MOSFETs are classified into n-channel or p-channel types based on the doping characteristics of their substrate and the source or drain regions.
In an n-MOSFET, the structure includes n-type source and drain...
700
Biasing of FET01:22

Biasing of FET

400
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...
400
Characteristics of MOSFET01:17

Characteristics of MOSFET

576
Metal-oxide-semiconductor field-effect Transistors, or MOSFETs, play a critical role in electronic circuits. They are primarily utilized for amplifying and switching signals.
Various vital parameters influence their functionality, which is crucial for theory and electronics applications. First, channel dimensions, precisely length, and width, are pivotal. The size of these channels affects the transistor's ability to carry current and switching speeds; shorter channels typically enable...
576

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Updated: Oct 22, 2025

Development and Functionalization of Electrolyte-Gated Graphene Field-Effect Transistor for Biomarker Detection
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Development and Functionalization of Electrolyte-Gated Graphene Field-Effect Transistor for Biomarker Detection

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2D Electronics Based on Graphene Field Effect Transistors: Tutorial for Modelling and Simulation.

Bassem Jmai1, Vitor Silva1, Paulo M Mendes1

  • 1CMEMS-UMinho, University of Minho, 4800-058 GuimarĂ£es, Portugal.

Micromachines
|August 27, 2021
PubMed
Summary
This summary is machine-generated.

This study offers simplified modeling and simulation tools for graphene field-effect transistors (GFETs), aiding system-level design. Researchers can now easily integrate GFET performance predictions into their work.

Keywords:
MATLABVHDL-AMSVeriloggraphene field-effect transistors (GFETs)modeling

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Area of Science:

  • Materials Science
  • Electrical Engineering
  • Semiconductor Device Physics

Background:

  • Graphene field-effect transistors (GFETs) offer unique electronic properties but lack accessible system-level design models.
  • Existing GFET models are often complex, hindering their adoption in circuit design.
  • Understanding the impact of device architecture (gate position, substrate, graphene growth) is crucial for GFET selection.

Purpose of the Study:

  • To provide simplified modeling and simulation tools for GFETs.
  • To facilitate the selection of appropriate GFET topologies for system-level design.
  • To enable researchers to predict GFET device performance easily.

Main Methods:

  • Development of a GFET model implemented in MATLAB, Verilog (Cadence), and VHDL-AMS (Simplorer).
  • Analysis of GFET architectures including top-gated, back-gated, and dual-gated configurations.
  • Exploration of various substrates (silicon, SiC, quartz/glass) and graphene growth methods (CVD, mechanical exfoliation).

Main Results:

  • A user-friendly GFET model is now available in multiple simulation environments.
  • The study provides insights into how device architecture influences GFET performance.
  • A tutorial guides researchers in implementing the model for performance prediction.

Conclusions:

  • The developed GFET model and tutorial simplify the integration of GFETs into system-level designs.
  • Accessible modeling tools are essential for accelerating GFET adoption in electronic circuits.
  • This work empowers researchers to effectively utilize GFETs in their designs.