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FinFETs and Their Impact on Modern Electronics

  • Contents

Overview: This article explores FinFET technology, detailing its structure, working principles, types, and advantages in modern semiconductor design, highlighting its impact on performance and miniaturization.

Over decades, transistors have greatly reduced in size from millimeters to tens of nanometers, allowing for greater functionality within microchips, which results in increased density and speed.

A MOSFET (Metal-Oxide-Semiconductor Field-Effect Transistors) is a type of transistor with four terminals: the Gate (G), Source (S), Drain (D), and Body (B), as shown in Fig. 1. The gate is the control terminal, while the source and drain are the terminals through which charge carriers enter and exit the channel. When a voltage is applied to the gate terminal, it creates an electric field that influences charge carriers in the substrate, and current flows from the source to the drain.

Diagrammatic illustration of a structure and working of MOSFET

Fig. 1 Diagrammatic illustration of a structure and working of MOSFET. Source: Rakesh Kumar, Ph.D.

The amount of current flowing through this channel is controlled by varying the gate voltage. Additionally, when the length (L), depicted in Fig. 1 of the gate electrode is reduced, the control of the gate over the channel region is also reduced, which lowers the transistor performance.

However, the short-channel effect is one of the important challenges of miniaturization. When the channel length is reduced to a point where it becomes comparable to the depletion layer widths of the source and drain junctions, the electrical characteristics of the device are impacted. Several other challenges include gate-induced drain leakage, diminished low power performance, threshold voltage shifts, etc.

Overcoming Challenges with Miniaturization of Transistors

Multi-gate field-effect transistors (MuGFETs) have emerged as an advancement in overcoming the limitations of traditional MOSFETs. This design minimizes short-channel effects by enhancing gate control over the channel region, which is important as devices scale down to sub-20 nm nodes. The most common type of MuGFET includes Fin Field-Effect Transistors.

FinFET

FinFET, or Fin Field-Effect Transistor, is an advanced type of MOSFET characterized by its three-dimensional structure where the channel forms vertical "fins" for enhanced electrical performance. This non-planar transistor design addresses the limitations of traditional planar MOSFETs. The FinFET design incorporates multiple gates that wrap around the channel, as shown in Fig. 2, providing improved electrostatic control over the channel. This configuration significantly reduces leakage currents and enhances drive current capabilities.

A comparison of the structure of a)MOSFET and b) FinFET

Fig. 2 A comparison of the structure of a)MOSFET and b) FinFET Source: MDPI

Structure of FinFET

The channel is formed by thin vertical fins made of semiconductor material, typically silicon. These fins extend upwards from the substrate, providing a larger effective channel area for current flow. The gate wraps around the fins on three sides (in tri-gate configurations), allowing superior electrostatic control over the channel.

A silicon dioxide layer (SiO₂) acts as an insulator between the gate and the channel, preventing direct electrical contact and enabling the gate to influence the channel’s conductivity through an electric field. The substrate is the base for the entire structure and can be either bulk silicon or silicon-on-insulator (SOI). The lightly doped p-type substrate supports the fins and helps isolate individual devices on a chip.

Working of FinFET

When a positive voltage is applied to the gate of an n-channel FinFET, it generates an electric field that attracts electrons from the source region to form an inversion layer in the p-type substrate beneath the gate oxide.

As the gate voltage exceeds a threshold (threshold voltage), this inversion layer allows current to flow between the source and drain. The channel formed by this inversion layer provides a conductive path for charge carriers.

Current flows from the source to the drain when a voltage is applied across these terminals. The amount of current flowing through this channel can be controlled by varying the gate voltage. If the gate voltage is below the threshold, no channel forms, resulting in no current flow (cutoff region). As voltage increases further, the current reaches saturation and stabilizes.

Types of FinFET

FinFETs may be divided into two primary groups according to the thickness of their dielectric, as shown in Fig. 3 as

  • Double-gate FinFET
  • Tri-gate FinFET

Double-Gate FinFET

A double-gate FinFET features a single-gate electrode that controls the channel from two opposite sides of the fin (front and back). This design is enhanced with a dielectric layer positioned above the fin, often called a hard mask. This layer inhibits the electric field from affecting the top of the fin, thereby preventing parasitic inversion channels at the corners of the fin.

Tri-Gate FinFET

In contrast, a tri-gate FinFET has a single gate electrode that wraps around three sides of the fin. This allows full control over the channel from three directions without any dielectric layer inhibiting the electric field above the fin. Double-gate and tri-gate FinFET are known for their lower parasitic capacitance, less complex structure, and manufacturing process.

Illustration of types FinFET a) Double-gate and b) Tri-gate FinFET

Fig. 3 Illustration of types FinFET a) Double-gate and b) Tri-gate FinFET. Source: MDPI

One of the advanced transistor architectures that enhances control over the channel by surrounding it with a gate on all sides is a gate all around FET.

Gate-all-around FET

Gate-all-around FET (GAA-FET) has improved gate coupling and enables precise channel tuning and lower short-channel effects. Unlike FinFETs, where the gate wraps around the channel on three sides, GAAFETs surround the channel on all four sides, as shown in Fig. 4. This provides superior electrostatic control over the channel, significantly reducing leakage currents and enhancing performance.

Diagrammatic illustration of the structure of MOSFET, FinFET, and Gate all around FET

Fig. 4 Diagrammatic illustration of the structure of MOSFET, FinFET, and Gate all around FET. Source: Semiconductor Engineering

 

Among gate-all-around FinFET topologies, nanosheets, as shown in Fig. 5, offer more "on" current and improved electrostatic control than FinFETs. In contrast, nanowires offer the greatest electrostatic control among various structures.

Diagrammatic illustration of the structure of nanowire and nanosheet gate all around FET

There are two primary forms of FinFET technology based on structural and functional characteristics, as shown in Fig. 6, which are

  • Bulk FinFETs
  • SOI (silicon on insulator) FinFETs

Illustration of FinFET types a) Bulk FinFETs b) SOI (silicon on insulator)

Fig. 6 Illustration of FinFET types a) Bulk FinFETs b) SOI (silicon on insulator). Source: MDPI

Bulk FinFETs

These FinFETs are built on bulk silicon and use fins etched directly onto the silicon substrate. They can perform well in sub-20 nm technology nodes while maintaining effective electrostatic control. The transition from planar MOSFETs to Bulk FinFETs is a relatively simple procedure because Bulk FinFETs closely resemble the traditional planar MOSFET structure.

SOI (silicon on insulator) FinFETs

These FinFETs are constructed on a silicon-on-insulator substrate, physically isolated fins that do not come into direct contact, allowing for better device isolation. Due to their reduced substrate coupling effects, SOI FinFETs can reduce parasitic capacitance and improve performance in high-speed applications.

Applications

FinFETs have a unique 3D structure and enhanced electrostatic control. In biosensing, they excel at detecting biomolecules like DNA and proteins through various configurations, including negative capacitance and junctionless designs, making them valuable for medical diagnostics.

Their chemical sensing capabilities are used in gas detection (particularly H₂ and PH₃), pH measurement, and ion sensing, with specialized designs like ion-sensitive floating gate FinFETs achieving high sensitivity. In physical applications, they've found great use in temperature sensing, especially in quantum computing, where bulk FinFETs operating in the Coulomb blockade regime provide precise temperature measurements in cryogenic environments.

Summarizing the Key Points

  • FinFETs enhance transistor performance by minimizing short-channel effects, improving electrostatic control, and reducing leakage currents, which are important for sub-20 nm technology nodes in microchips.
  • Gate-all-around FETs improve gate coupling and channel tuning, offering superior control over short-channel effects compared to traditional FinFET designs and enhancing overall device performance.
  • The transition from planar MOSFETs to FinFETs represents a significant advancement in semiconductor technology, enabling higher density and speed in microchips while addressing miniaturization challenges.

Reference

Karimi, K., Fardoost, A., & Javanmard, M. (2024). Comprehensive review of FinFET Technology: history, structure, challenges, innovations, and emerging sensing applications. Micromachines, 15(10), 1187. https://doi.org/10.3390/mi15101187

Madhavi, K. B., & Tripathi, S. L. (2020). Strategic Review on different materials for FinFET Structure Performance Optimization. IOP Conference Series Materials Science and Engineering, 988(1), 012054. https://doi.org/10.1088/1757-899x/988/1/012054

Review on Fin Shape Channel Field Effect Transistor (FinFET)-Journal of Electronics Electromedical Engineering and Medical Informatics

Gate-All-Around FET (GAA FET)-Semiconductor Engineering

GAA Structure Transistors- Samsung

Rakesh Kumar, Ph.D.

Rakesh Kumar holds a Ph.D. in electrical engineering, specializing in power electronics. He is a Senior Member of the IEEE Power Electronics Society, Class of 2021. He writes high-quality, long-form technical articles for global B2B semiconductor brands. Feel free to reach out to him at rakesh.a@ieee.org! Checkout his complete portfolio @muckrack.com/rakesh-kumar-phd | @linkedin.com/in/rakesh-kumar-phd

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