VISHAY AN101

AN101
An Introduction to FETs
The family tree of FET devices (Figure 1) may be divided
into two main branches, Junction FETs (JFETs) and Insulated Gate FETs (or MOSFETs, metal-oxide- semiconductor field-effect transistors). Junction FETs are inherently depletion-mode devices, and are available in
both n- and p-channel configurations. MOSFETs are
available in both enhancement and depletion modes, and
also exist as both n- and p-channel devices. The two main
FET groups depend on different phenomena for their operation, and will be discussed separately.
Introduction
The basic principle of the field-effect transistor (FET) has
been known since J. E. Lilienfeld’s patent of 1925. The
theoretical description of a FET made by Shockley in
1952 paved the way for development of a classic electronic device which provides the designer the means to accomplish nearly every circuit function. At one time, the
field-effect transistor was known as a “unipolar” transistor. The term refers to the fact that current is transported
by carriers of one polarity (majority), whereas in the conventional bipolar transistor carriers of both polarities
(majority and minority) are involved.
Junction FETs
This Application Note provides an insight into the nature of
the FET, and touches briefly on its basic characteristics, terminology, parameters, and typical applications.
The following list of FET applications indicates the versatility of the FET family:
Amplifiers
Switches
Small Signal
Chopper-Type
Low Distortion
Analog Gate
High Gain
Communicator
Low Noise
Protection Diodes
Selectivity
Low-leakage
DC
High-Frequency
Current Limiters
Voltage-Controlled Resistors
Mixers
Oscillators
In its most elementary form, this transistor consists of a
piece of high-resistivity semiconductor material (usually
silicon) which constitutes a channel for the majority carrier flow. The magnitude of this current is controlled by a
voltage applied to a gate, which is a reverse-biased pn
junction formed along the channel. Implicit in this description is the fundamental difference between JFET and
bipolar devices: when the JFET junction is reverse-biased
the gate current is practically zero, whereas the base current of the bipolar transistor is always some value greater
than zero. The JFET is a high-input resistance device,
while the input resistance of the bipolar transistor is comparatively low. If the channel is doped with a donor impurity, n-type material is formed and the channel current
will consist of electrons. If the channel is doped with an
acceptor impurity, p-type material will be formed and the
channel current will consist of holes. N-channel devices
have greater conductivity than p-channel types, since
electrons have higher mobility than do holes; thus n-channel JFETs are approximately twice as efficient conductors
compared to their p-channel counterparts.
FETs
Junction
Enhancement
Not Possible
Depletion
n
MOS
p
Depletion
n
Enhancement
p
n
p
Figure 1. FET Family Tree
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AN101
In addition to the channel material, a JFET contains two
ohmic (non-rectifying) contacts: the source and the drain.
These are shown in Figure 2. Since a symmetrical geometry is shown in the idealized JFET chip, it is immaterial
which contact is called the source and which is called the
drain; the JFET will conduct current equally well in either
direction and the source and drain leads are usually interchangeable.
layer as VDS increases. The curve approaches the level of
the limiting current IDSS when ID begins to be pinched off.
The physical meaning of this term leads to one definition
of pinch-off voltage, VP , which is the value of VDS at
which the maximum IDSS flows.
VDS < VP
N-Source
Channel
N-Drain
S
D
P
N
Depletion
Layer
P
N-Channel
P-Gate
G
Final form taken by FET with n-type channel embedded in p-type
substrate.
Figure 2. Idealized Structure of An N-Channel
Junction FET
3a) N-Channel FET Working in the Ohmic Region (VGS =
0 V) (Depletion Shown Only in Channel Region)
(For certain JFET applications, such as high-frequency
amplifiers, an asymmetrical geometry is preferred for
lower capacitance and improved frequency response. In
these cases, the source and drain leads should not be interchanged.)
VDS > VP
S
D
P
N
Figure 3 shows how the JFET functions. If the gate is connected to the source, then the applied voltage (VDS) will
appear between the gate and the drain. Since the pn junction is reverse-biased, little current will flow in the gate
connection. The potential gradient established will form
a depletion layer, where almost all the electrons present
in the n-type channel will be swept away. The most depleted portion is in the high field between the gate and the
drain, and the least-depleted area is between the gate and
the source. Because the flow of current along the channel
from the (positive) drain to the (negative) source is really
a flow of free electrons from source to drain in the n-type
silicon, the magnitude of this current will fall as more silicon becomes depleted of free electrons. There is a limit
to the drain current (ID) which increased VDS can drive
through the channel. This limiting current is known as
IDSS (Drain-to-Source current with the gate shorted to the
source). Figure b shows the almost complete depletion of
the channel under these conditions.
Depletion
Layer
P
G
3b) N-Channel FET Working in the Current Saturation
Region (VGS = 0)
IDSS
Saturation Region
Current
ID
VGS = 0 V
Ohmic
Region
VP
VDS
3c) Idealized Output Characteristic for VGS = 0
Figure 3.
Figure 3c shows the output characteristics of an n-channel
JFET with the gate short-circuited to the source. The
initial rise in ID is related to the buildup of the depletion
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AN101
In Figure 4, consider the case where VDS = 0 and where
a negative voltage VGS is applied to the gate. Again, a
depletion layer has built up. If a small value of VDS were
now applied, this depletion layer would limit the resultant
channel current to a value lower than would be the case
for VGS = 0. In fact, at a value of VGS > VP the channel
current would be almost entirely cut off. This cutoff voltage is referred to as the gate cutoff voltage, and may be
expressed by the symbol VP or by VGS(off). VP has been
widely used in the past, but VGS(off) is now more commonly accepted since it eliminates the ambiguity between gate cut-off and drain pinch-off.
Depletion
Layer
S
D
P
N
VGS
P
G
Figure 4. N-Channel FET Showing Depletion Due to
Gate-Source Voltage and VDS = 0
The mechanisms of Figures 3 and 4 react together to provide the family of output characteristics shown in Figure
5a. The area below the pinch-off voltage locus is known
as the ohmic region: the area above pinch-off is current
saturation region. JFETs operating in the current saturation region make excellent amplifiers. Note that in the
ohmic region both VGS and VDS control the channel current, while in the current saturation region VDS has little
effect and VGS essentially controls ID.
Figure 5b relates the curves in Figure 5a to the actual circuit arrangement, and shows the number of meters which
may be connected to display the conditions relevant to
any combination of VDS and VGS. Note that the direction
of the arrow at the gate gives the direction of current flow
for the forward-bias condition of the junction. In practice,
however, it is always reverse-biased.
The p-channel JFET works in precisely the same way as
the n-channel JFET. In manufacture, the planar process is
essentially reversed, with the acceptor impurity diffused
first onto n-type silicon, and the donor impurity diffused
later to form a second n-type region and leave a p-type
channel. In the p-channel JFET, the channel current is due
to hole movement, rather than to electron mobility. Consequently, all the applied polarities are reversed, along
with their directions and the direction of current flow.
In summary, a junction FET consists essentially of a channel of semiconductor material along which a current may
flow whose magnitude is a function of two voltages, VDS
and VGS. When VDS is greater than VP, the channel current is controlled largely by VGS alone, because VGS is applied to a reverse-biased junction. The resulting gate current is extremely small.
ID
VDS = VP – VGS
IDSS
ID
VGS = 0
+
–
D
G
ID
VGS = –V
VDS
S
–
VGS
0
VDS
VP
+
VGS(off)
5a) Family of Output Characteristics
for N-Channel FET
5b) Circuit Arrangement for N-Channel FET
Figure 5.
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AN101
MOSFETs
The metal-oxide-semiconductor FET (MOSFET) depends
on the fact that it is not actually necessary to form a semiconductor junction on the channel of a FET to achieve gate
control of the channel current. On a MOSFET, the metallic
or polysilicon gate is isolated from the channel by a thin layer of silicon dioxide (Figure 6a). Although the bottom of the
insulating layer is in contact with the p-type silicon substrate, the physical processes which occur at this interface
dictate that free electrons will accumulate in the interface,
inverting the p-type material and spontaneously forming an
n-type channel. Thus, a conduction path exists between the
diffused n-type channel source and drain regions.
There are, however, some fundamental performance differences between MOSFETs and JFETS. JFETs, by nature, operate only in the depletion mode. That is, a reverse
gate bias depletes, or pinches off the flow of channel current. A MOSFET, by virtue of its electrically-insulated
gate, can be fabricated to perform as either a depletionmode or enhancement-mode FET. Quite unlike the JFET,
a depletion-mode MOSFET will also perform as an enhancement-mode FET.
While the great majority of JFETs operate as described in
Figures 3 and 4, MOSFETs can assume several forms and
operate in either the depletion/enhancement-mode or enhancement-mode only.
G
S
ID
D
Insulating
Layer
Metal
N
ID
+
D
N
–
VDS
G
P
S
VGS
Substrate
6a) Idealized Cross-Section Through an
N-Channel Depletion-Type MOSFET
6b) Circuit Arrangement for
N-Channel Depletion MOSFET
VDS = VGS – VGS(th)
Ohmic Region Characteristics
Ohmic Region Characteristics
VGS = 0.2 V
VGS = 10 V
0V
160
–0.2 V
120
–0.4 V
80
–0.6 V
40
6V
1.0
ID – Drain Current (A)
ID – Drain Current (mA)
200
5V
TJ = 25_C
0.8
4V
0.6
0.4
3V
0.2
–0.8 V
–1 V
2V
0
0
0
0.4
0.8
1.2
1.6
0
2.0
VDS – Drain-Source Voltage (V)
1.0
2.0
3.0
4.0
5.0
VDS – Drain-Source Voltage (V)
6c) Family of Output Characteristics
for N-Channel Depletion MOSFET
6d) Family of Output Characteristics for
N-Channel Enhancement MOSFET
Figure 6.
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There are three types of small-signal MOSFETs. First, we
have the planar, lateral MOSFET, similar to that shown in
Figure 6a. By virtue of the n-doped channel spanning
from source to drain, it performs as an n-channel depletion-mode MOSFET in a fashion not unlike that of the
depletion-mode JFET when a voltage of the correct polarity is applied to the gate, as in Figure 6b. However, if we
forward-bias the gate (that is, place a gate voltage whose
polarity equals the drain voltage polarity) additional electrons will be attracted to the region beneath the gate, further enhancing – and inverting (from p to n) the region.
As the channel region thickens, the channel resistance
will further decrease, allowing greater channel current to
flow beyond that identified as IDSS, as we see in the family
of output characteristics in Figure 6c.
MOSFETs can also be constructed for enhancement mode-only performance, as shown in Figure 7. Unlike the
depletion-mode device, the enhancement-mode MOSFET
offers no channel between the source and drain. Not until a
forward bias on the gate enhances a channel by attracting
electrons beneath the gate oxide will current begin to flow
(Figure 6d).
Gate
Source
Drain
ÉÉÉÉÉÉÉÉÉÉÉÉÉ
ÉÉÉÉÉÉÉÉÉÉÉÉÉ
Oxide
N
N
P-Silicon
precisely-defined short channel that results and the “drift
region” resulting from the remaining p-doped silicon
body and light n-doped ion implant.
Gate
ÉÉÉÉÉÉÉÉÉÉÉÉÉ
ÉÉÉÉÉÉÉÉÉÉÉÉÉ
Source
Oxide
N+
N+
P
N–
P-Silicon
Substrate
Figure 8. Planar Enhancement-Mode DMOS
Although Figures 7 and 8 illustrate n-channel enhancement-mode DMOS FETs, by reversing the doping sequences, p-channel DMOS FETs can easily be fabricated.
Furthermore, by lightly doping across the short channel
and drift region, depletion-mode DMOS FETs can be
constructed.
As a result of the short channel, the MOSFET is allowed
to operate in “velocity saturation” and as a result of the
drift region, the MOSFET offers higher operating voltages. Together, the short channel and the drift region offer
low on-resistance and low interelectrode capacitances,
especially gate-to-drain, VGD.
Velocity saturation coupled with low interelectrode capacitance offers us high-speed and high-frequency performance.
Body
N–
Source
Gate
Figure 7. Planar Enhancement-Mode MOS Cross-Section
A newer MOSFET offering superior performance is the
lateral double-diffused or DMOS FET. Because of the limitations of photo-lithographic masking, the earlier, older-style MOSFET was severely limited in performance.
Some of these former limitations involved switching
speeds, channel conductivity (too high an rDS), and current handling in general. The lateral DMOS FET removed
these limitations, offering a viable alternative between
the JFET and the GaAs FET for video and high-speed
switching applications.
The lateral DMOS FET differs radically in its channel
construction when compared with the older planar MOSFET. Note the double-diffused source implant into the implanted p-doped channel region, shown in Figure 8. The
improved performance of DMOS is a result of both the
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Drain
Metal
N–
ÉÉÉ
ÉÉÉÉÉÉ
P+
Metal
P+
N+
Drain
Figure 9. Vertical N-Channel Enhancement-Mode
DMOS FET
The novelty of the short-channel DMOS FET led to the
evolution of a yet more advanced, higher-voltage, highercurrent MOSFET: the Vertical Double-Diffused MOSFET
(Figure 9). Where this vertical MOSFET offers improved
power-handling capabilities, its fundamental shortcoming is
that because of its construction and to a lesser extent because
of its size, it fails to challenge the high-speed performance
of the lateral DMOS FET. Consequently, the vertical and lateral DMOS FETs complement each other in a wide selection
of applications.
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