device FinFET
MOSFET from 2016, which uses a 16 nm FinFET-based
Pascal chip manufactured by TSMC
FinFET (fin field-effect transistor) is a type of non-planar transistor, or "3D" transistor (not to be confused with
3D microchips). The FinFET is a variation on traditional MOSFETs distinguished by the presence of a thin silicon "fin" inversion channel on top of the substrate, allowing the gate to make two points of contact: the left and right sides of the fin. The thickness of the fin (measured in the direction from source to drain) determines the effective channel length of the device. The wrap-around gate structure provides a better electrical control over the channel and thus helps in reducing the leakage current and overcoming other
short-channel effects. The first FinFET transistor type was called a
depleted lean-channel transistor or "DELTA" transistor, which was first
fabricated by
Hitachi Central Research Laboratory's Digh Hisamoto, Toru Kaga, Yoshifumi Kawamoto and Eiji Takeda in 1989. In the late 1990s, Digh Hisamoto began collaborating with an international team of researchers on further developing DELTA technology, including
TSMC's
Chenming Hu and a
UC Berkeley research team including
Tsu-Jae King Liu,
Jeffrey Bokor, Xuejue Huang, Leland Chang, Nick Lindert, S. Ahmed, Cyrus Tabery, Yang-Kyu Choi, Pushkar Ranade, Sriram Balasubramanian, A. Agarwal and M. Ameen. In 1998, the team developed the first
N-channel FinFETs and successfully fabricated devices down to a
17nm process. The following year, they developed the first
P-channel FinFETs. They coined the term "FinFET" (fin field-effect transistor) in a December 2000 paper. In current usage the term FinFET has a less precise definition. Among
microprocessor manufacturers,
AMD,
IBM, and
Freescale describe their double-gate development efforts as FinFET development, whereas
Intel avoids using the term when describing their closely related tri-gate architecture. In the technical literature, FinFET is used somewhat generically to describe any fin-based, multigate transistor architecture regardless of number of gates. It is common for a single FinFET transistor to contain several fins, arranged side by side and all covered by the same gate, that act electrically as one, to increase drive strength and performance. The gate may also cover the entirety of the fin(s). A 25 nm transistor operating on just 0.7
volt was demonstrated in December 2002 by
TSMC (Taiwan Semiconductor Manufacturing Company). The "Omega FinFET" design is named after the similarity between the Greek letter
omega (Ω) and the shape in which the gate wraps around the source/drain structure. It has a
gate delay of just 0.39
picosecond (ps) for the N-type transistor and 0.88 ps for the P-type. In 2004,
Samsung Electronics demonstrated a "Bulk FinFET" design, which made it possible to mass-produce FinFET devices. They demonstrated dynamic
random-access memory (
DRAM) manufactured with a
90nm Bulk FinFET process. In 2011,
Rice University researchers Masoud Rostami and Kartik Mohanram demonstrated that FINFETs can have two electrically independent gates, which gives circuit designers more flexibility to design with efficient, low-power gates. In 2012, Intel started using FinFETs for its future commercial devices. Leaks suggest that Intel's FinFET has an unusual shape of a triangle rather than rectangle, and it is speculated that this might be either because a triangle has a higher structural strength and can be more reliably manufactured or because a triangular prism has a higher area-to-volume ratio than a rectangular prism, thus increasing switching performance. In September 2012,
GlobalFoundries announced plans to offer a 14-nanometer process technology featuring FinFET three-dimensional transistors in 2014. The next month, the rival company
TSMC announced start early or "risk" production of 16 nm FinFETs in November 2013. In March 2014,
TSMC announced that it is nearing implementation of several
16 nm FinFETs
die-on wafers manufacturing processes: • 16 nm FinFET (Q4 2014), • 16 nm FinFET+ ( Q4 2014), • 16 nm FinFET "Turbo" (estimated in 2015–2016).
AMD released GPUs using their Polaris chip architecture and made on 14 nm FinFET in June 2016. The company has tried to produce a design to provide a "generational jump in power efficiency" while also offering stable frame rates for graphics, gaming, virtual reality, and multimedia applications. In March 2017,
Samsung and
eSilicon announced the
tapeout for production of a 14 nm FinFET ASIC in a 2.5D package.
Tri-gate transistor A
tri-gate transistor, also known as a triple-gate transistor, is a type of MOSFET with a gate on three of its sides. A triple-gate transistor was first demonstrated in 1987, by a
Toshiba research team including K. Hieda, Fumio Horiguchi and H. Watanabe. They realized that the fully depleted (FD) body of a narrow bulk
Si-based transistor helped improve switching due to a reduced body-bias effect. In 1992, a triple-gate MOSFET was demonstrated by
IBM researcher Hon-Sum Wong. Intel announced this technology in September 2002. Intel announced "triple-gate transistors" which maximize "transistor switching performance and decreases power-wasting leakage". A year later, in September 2003,
AMD announced that it was working on similar technology at the International Conference on Solid State Devices and Materials. No further announcements of this technology were made until Intel's announcement in May 2011, although it was stated at IDF 2011, that they demonstrated a working
SRAM chip based on this technology at IDF 2009. On April 23, 2012, Intel released a new line of CPUs, termed
Ivy Bridge, which feature tri-gate transistors. Intel has been working on its tri-gate architecture since 2002, but it took until 2011 to work out mass-production issues. The new style of transistor was described on May 4, 2011, in San Francisco. It was announced that Intel's factories were expected to make upgrades over 2011 and 2012 to be able to manufacture the Ivy Bridge CPUs. It was announced that the new transistors would also be used in Intel's
Atom chips for low-powered devices. Intel explains: "The additional control enables as much transistor current flowing as possible when the transistor is in the 'on' state (for performance), and as close to zero as possible when it is in the 'off' state (to minimize power), and enables the transistor to switch very quickly between the two states (again, for performance)." Intel has stated that all products after
Sandy Bridge will be based upon this design. The term
tri-gate is sometimes used generically to denote any multigate FET with three effective gates or channels. ==Gate-all-around FET (GAAFET)==