Introduction to MOSFETs (EST 160) PDF

Summary

This presentation introduces MOSFETs and covers topics such as doping, mobility, and MOSFET symbols. It also outlines MOSFET structure, operation as a switch, and characteristics. It also includes information about voltage limitations. It is part of an introduction to Analog Circuits Design (EST 160) course.

Full Transcript

Introduction to MOSFETs

Introduction to Analog Circuits Design
(EST 160)

Prepared by: Engr. Rochelle M. Sabarillo
What is Doping?
Doping is the process of intentionally adding impurities to a
semiconductor in order to change its electrical properties.

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What is Doping?
In short, doping is used to increase electron or hole concentration.

A dopant, also called a doping agent, is any impurity deliberately added to a
semiconductor for the purpose of modifying its electrical conductivity.

Related illustration: https://www.youtube.com/watch?v=Q5FnIv-pDEQ
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Mobility
In solid-state physics, the electron mobility characterises how quickly an electron can
move through a metal or semiconductor, when pulled by an electric field. There is an
analogous quantity for holes, called hole mobility. The term carrier mobility refers in
general to both electron and hole mobility.

The only difference between electrons and holes is in their energy and, therefore, in
velocity. The effective mass is a result of electron interaction with lattice, i.e. with
phonons. As the hole velocity is smaller, a hole spends more time in the interaction
region, i.e. holes strongly interact with phonons.

The mobility is inversely proportional to the effective mass and the effective mass of
hole is much higher than that of electron. Thus the electron mobility is higher than
that of hole.

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Depletion MOSFET vs. Enhancement MOSFET

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MOSFET Symbols
The circuit symbols used to represent NMOS and PMOS transistors are shown below:

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MOSFET as a Switch
Shown below is the symbol for an n-type MOSFET, revealing three terminals: gate
(G), source (S), and drain (D). The latter two are interchangeable because the device
is symmetric.

When operating as a switch, the transistor “connects” the source and the drain
together if the gate voltage, VG, is “high” and isolates the source and the drain if V G
is “low.

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MOSFET Structure
Figure below shows a simplified structure of an n-type MOS (NMOS) device. Fabricated on a p-type
substrate (also called the “bulk” or the “body”), the device consists of two heavily-doped n
regions forming the source and drain terminals, a heavily-doped (conductive) piece of polysilicon
(simply called “poly”) operating as the gate, and a thin layer of silicon dioxide (SiO2) (simply
called “oxide”) insulating the gate from the substrate. The useful action of the device occurs in the
substrate region under the gate oxide. Note that the structure is symmetric with respect to S and
D.

The lateral dimension of the gate along the source-drain path is called the length, L, and that
perpendicular to the length is called the width, W.

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MOSFET Structure
In reality, the substrate potential greatly influences the device characteristics. That is, the MOSFET
is a four-terminal device.

Since in typical MOS operation, the S/D junction diodes must be reverse-biased, we assume that
the substrate of NMOS transistors is connected to the most negative supply in the system. For
example, if a circuit operates between zero and 1.2 volts, V sub,NMOS = 0.

The actual connection is usually provided through an ohmic p+ region, as depicted in the side view
of the device below:

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MOSFET Structure
In complementary MOS (CMOS) technologies, both NMOS and PMOS transistors are available. From a
simplistic viewpoint, the PMOS device is obtained by negating all of the doping types (including the
substrate) [(a)], but in practice, NMOS and PMOS devices must be fabricated on the same wafer, i.e.,
the same substrate.

For this reason, one device type can be placed in a “local substrate,” usually called a “well.” In
today’s CMOS processes, the PMOS device is fabricated in an n-well [(b)]. Note that the n-well must be
connected to a potential such that the S/D junction diodes of the PMOS transistor remain reverse-
biased under all conditions. In most circuits, the n-well is tied to the most positive supply voltage.

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MOSFET Structure
Figure (b) indicates an interesting difference between NMOS and PMOS transistors: while all NFETs
share the same substrate, each PFET can have an independent n-well. This flexibility of PFETs is
exploited in some analog circuits.

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Threshold Voltage: VTH
NMOS
What happens as the gate voltage, VG, increases from zero? Since the gate, the dielectric, and the
substrate form a capacitor, as VG becomes more positive, the holes in the p-substrate are repelled from
the gate area, leaving negative ions behind so as to mirror the charge on the gate. In other words, a
depletion region is created (Figure b). Under this condition, no current flows because no charge carriers
are available.

As VG increases, so do the width of the depletion region and the potential at the oxide-silicon
interface. In a sense, the structure resembles a voltage divider consisting of two capacitors in series:
the gate-oxide capacitor and the depletion-region capacitor (Figure c).

When the interface potential reaches a sufficiently positive value, electrons flow from the source to the
interface and eventually to the drain. Thus, a “channel” of charge carriers is formed under the gate
oxide between S and D, and the transistor is “turned on.” We say the interface is “inverted.” For this
reason, the channel is also called the “inversion layer.”

The value of VG for which this occurs is called the “threshold voltage,” VTH. If VG rises further, the
charge in the depletion region remains relatively constant while the channel charge density continues to
increase, providing a greater current from S to D. The NMOS device turns on abruptly for VGS ≥ VTH.
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MOS I/V Characteristics

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Threshold Voltage: VTH
PMOS
The turn-on phenomenon in a PMOS device is similar to that of NFETs, but with all the polarities
reversed.

As shown in the figure below, if the gate-source voltage becomes sufficiently negative, an inversion
layer consisting of holes is formed at the oxide-silicon interface, providing a conduction path between
the source and the drain. That is, the threshold voltage of a PMOS device is typically negative. The PMOS
device turns on abruptly for VSG ≥ |VTH|.

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vs

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MOSFET Operating Regions
1.Cut-off
2.Linear/Triode/Ohmic
3.Saturation

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Triode Region
Since ID is constant along the channel,

Note that L is the effective channel length.

Figure here plots the parabolas given by the
equation above for different values of VGS,
indicating that the “current capability” of the
device increases with VGS.

The peak of each parabola occurs at VDS = VGS −
VTH and the peak current is

VGS − VTH the “overdrive voltage” and W/L the
“aspect ratio.” If VDS ≤ VGS − VTH, we say the
device operates in the “triode region.”
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Deep Triode Region
If VDS