The MOSFET circuit
technology has dramatically changed over the last three decades.
Starting with a ten-micron pMOS process with an aluminum gate and a
single metallization layer around 1970, the technology has evolved into a
tenth-micron self-aligned-gate CMOS process with up to five
metallization levels. The transition from dopant diffusion to ion
implantation, from thermal oxidation to oxide deposition, from a metal
gate to a poly-silicon gate, from wet chemical etching to dry etching
and more recently from aluminum (with 2% copper) wiring to copper wiring
has provided vastly superior analog and digital CMOS circuits.
MOSFET fabrication process
|  |
| A quick look at the
history of the MOSFET fabrication process reveals that it has evolved
significantly over the years. Around 1970, pMOS circuits with aluminum
gate metal and wiring were dominant. The corresponding steps of a
typical pMOSFET fabrication process steps are listed in Table 7.6.1. |
| Table 7.6.1: | pMOS process steps |
| The primary problem at
the time was threshold voltage control. Positively charged ions in the
oxide decreased the threshold voltage of the devices. p-type
MOSFETs were therefore the device of choice despite the lower hole
mobility, since they would still be enhancement-type devices even when
charge was present. Circuits were still operational at somewhat higher
power supply voltages despite the presence of some residual charge in
the oxide. |
| Thermal oxidation of
the silicon in an oxygen or water vapor atmosphere provided a quality
gate oxide with easily controlled thickness. The same process was also
used to provide a high-temperature mask for the diffusion process and a
passivation and isolation layer. Some people claim that the quality and
versatility of silicon’s oxide made silicon the preferred semiconductor
over germanium. |
| The oxide was easily
removed in hydrofluoric acid (HF), without removing the underlying
silicon, thanks to the high selectivity if the etch. |
| Aluminum was
evaporated over the whole wafer and then etched yielding both the gate
metal and the metal wiring connecting the devices. A small amount of
copper (~2%) was added to make the aluminum more resistant to
electromigration. Electromigration is the movement of atoms due to the
impact with the electrons carrying the current through the wire. This
effect can cause open circuits and is therefore a well-known reliability
problem. It typically occurs at points where the local current density
is very high, in narrow wires, at corners or when crossing an oxide
step. The addition of a small amount of copper provides a more rigid
structure within the aluminum and eliminates the effect. |
| Annealing the metal in a nitrogen/hydrogen (N2/H2)
ambient was used to improve the metal-semiconductor contact and to
reduce the surface state density at the semiconductor/gate-oxide
interface. |
| Since then the fabrication process has changed as illustrated with Table 7.6.2.
Most changes were introduced to provide superior performance, better
reliability and higher yield. The most important change has been the
reduction of the gate length. A gate length reduction provides a shorter
transit time and hence a faster device. In addition, a gate length
reduction is typically linked to a reduction of the minimum feature size
and therefore yields smaller transistors as well as a larger number of
transistors on a chip with a given size. As the technology improved, it
was also possible to make larger chips, so that the number of
transistors per chip increased even faster. At the same time, the wafer
size was increased to accommodate the larger chips while reducing the
loss due to partial chips at the wafer periphery. Larger wafers further
reduce the cost per chip as more chips can be accommodated on a single
wafer. |
| The other changes can
be split into process improvements and circuit improvements. The
distinction is at times artificial, as circuit improvements typically
require new processes. |
| The key circuit
improvement is the use of CMOS circuits, containing both nMOS and pMOS
transistors. Early on, the pMOS devices were replaced with nMOS
transistors because of the better electron mobility. Enhancement-mode
loads were replaced for first by resistor loads and then by
depletion-mode loads yielding faster logic circuits with larger
operating margins. Analog circuits benefited in similar ways. The use of
complementary circuits was first introduced by RCA but did not
immediately catch on since the logic circuits were somewhat slower and
larger than the then-dominant nMOS depletion logic. It was only when the
number of transistors per chip became much larger that the inherent
advantages of CMOS circuits became clear. CMOS circuits have a lower
power dissipation and larger operating margin. They became the
technology of choice as thousands of devices we integrated on a single
chip. Today, the CMOS technology is the dominant technology in the IC
industry as the ten-fold reduction of power dissipation largely
outweighs the 30%-50% speed reduction and size increase. |
| The process
improvements can in turn be split into those aimed at improving the
circuit performance and those improving the manufacturability and
reliability. Again the split is somewhat artificial but it is beneficial
to understand what factors affect the process changes. The latter group
includes CVD deposition, ion implantation, RIE etching, sputtering,
planarization and deuterium annealing. The process changes, which
improve the circuit performance, are the self-aligned poly-silicon gate
process, the silicide gate cap, LOCOS isolation, multilevel wiring and
copper wiring. |
| The self-aligned
poly-silicon gate process was introduced before CMOS and marked the
beginning of modern day MOSFETs. The self-aligned structure, as further
discussed in section 7.6.2,
is obtained by using the gate as the mask for the source-drain implant.
Since the crystal damage caused by the high-energy ions must be
annealed at high temperature (~800 C), an aluminum gate could no longer
be used. Doped poly-silicon was found to be a very convenient gate
material since it withstands the high anneal temperature and can be
oxidized just like silicon. The self-aligned process lowers the
parasitic capacitance between gate and drain and therefore improves the
high-frequency performance and switching time. The addition of a
silicide layer on top of the gate reduces the gate resistance while
still providing a quality implant mask. The self-aligned process also
reduced the transistor size and hence increased the density. The field
oxide was replaced by a local oxidation isolation structure (LOCOS),
where a Si3N4 layer is used to prevent the
oxidation in the MOSFET region. This oxide provides an implant mask and
contact hole mask yielding an even more compact device. |
| Multilevel wiring is a
necessity when one increases the number of transistors per chip. After
all, the number of wires increases with the square of the number of
transistors and the average wire length increase linearly with the chip
size. While multilevel wiring simply consists of a series of metal
wiring levels separated by insulators, the multilevel wiring has
increasingly become a bottleneck in the fabrication of high-performance
circuits. Planarization techniques, as discussed below, and the
introduction of copper instead of aluminum-based metals have further
increased the wiring density and lowered the wiring resistance. |
| Table 7.6.2: | MOS process changes and improvements |
| Chemical vapor
deposition (CVD) of insulating layers is now used instead of thermal
oxidation since it does not consume the underlying silicon. Also,
because there is no limit to the obtainable thickness and since
materials other than SiO2 (for instance Si3N4) can be deposited. CVD deposition is also frequently used to deposit refractory metals such as tungsten. |
| Ion implantation has
replaced diffusion because of its superior control and uniformity. Dry
etching including plasma etching, reactive ion etching (RIE) and ion
beam etching has replaced wet chemical etching. These etch processes
provide better etch rate uniformity and control as well as very
pronounced anisotropic etching. The high etch rate selectivity of wet
chemical etching is not obtained with these dry etch techniques, but are
well compensated by the better uniformity. |
| Sputtering of metals
has completely replaced evaporation. Sputtering typically provides
better adhesion and thickness control. It is also better suited to
deposit refractory metals and silicides. |
| Planarization is the
process by which the top surface of the wafer is planarized after each
step. The purpose of this planarization process is to provide a flat
surface, so that fine-line lithography can be performed at all stages of
the fabrication process. The planarization enables high-density
multi-layer wiring levels. |
| Deuterium anneal is a
recent modification of the standard hydrogen anneal, which passivates
the surface states. The change to deuterium was prompted because it is a
heavier isotope of hydrogen. It chemically acts the same way but is
less likely to be knocked out of place by the energetic carriers in the
inversion layer. The use of deuterium therefore reduces the increase of
the surface state density due to hot-electron impact. |
Poly-silicon gate technology
| |
| An early improvement
of the technology was obtained by using a poly-silicon gate. Such gate
yields a compact self-aligned structure with better performance. The
poly-silicon gate is used as a mask during the implantation so that the
source and drain regions are self-aligned with respect to the gate. This
self-alignment structure reduces the device size. In addition, it
eliminates the large overlap capacitance between gate and drain, while
maintaining a continuous inversion layer between source and drain. |
| A further improvement
of this technique is the use of a low-doped drain (LDD) structure. As an
example we consider the structure shown in Figure 7.6.1.
Here a first shallow implant is used to contact the inversion layer
underneath the gate. The shallow implant causes only a small overlap
between the gate and source/drain regions. After adding a sidewall to
the gate a second deep implant is added to the first one. This deep
implant has a low sheet resistance and adds a minimal series resistance.
The combination of the two implants therefore yields a minimal overlap
capacitance and low access resistance. |
| Figure 7.6.1: | Cross-sectional view of a self-aligned poly-silicon gate transistor with LOCOS isolation |
| Shown is also the
local oxidation isolation (LOCOS). Typically, there would also be an
additional field and channel implant. The field implant increases the
doping density under the oxide and thereby increases the threshold
voltage of the parasitic transistor formed by the metal wiring on top of
the isolation oxide. The channel implant provides an adjustment of the
threshold voltage of the transistors. The use of a poly-silicon gate has
the disadvantage that the sheet resistance of the gate is much larger
than that of a metal gate. This leads to high RC time-constants of long
poly-silicon lines. Silicides (WSi, TaSi, CoSi etc.) or a combination of
silicides and poly-silicon are used to reduce these RC delays. Also by
using the poly-silicon only as gate material and not as a wiring level
one can further eliminated such RC time delays. |
| Complementary
Metal-Oxide-Silicon circuits require an nMOS and pMOS transistor
technology on the same substrate. To this end, an n-type well is provided in the p-type substrate. Alternatively one can use a p-well or both an n-type and p-type
well in a low-doped substrate. The gate oxide, poly-silicon gate and
source-drain contact metal are typically shared between the pMOS and
nMOS technology, while the source-drain implants must be done
separately. Since CMOS circuits contain pMOS devices, which are affected
by the lower hole mobility, CMOS circuits are not faster than their
all-nMOS counter parts. Even when scaling the size of the pMOS devices
so that they provide the same current, the larger pMOS device has a
higher capacitance. |
| The CMOS advantage is
that the output of a CMOS inverter can be as high as the power supply
voltage and as low as ground. This large voltage swing and the steep
transition between logic levels yield large operation margins and
therefore also a high circuit yield. In addition, there is no power
dissipation in either logic state. Instead the power dissipation occurs
only when a transition is made between logic states. CMOS circuits are
therefore not faster than nMOS circuits but are more suited for
very/ultra large-scale integration (VLSI/ULSI). |
| CMOS circuits have one property, which is very undesirable, namely latchup. Latchup occurs when four alternating p-type and n-type
regions are brought in close proximity. Together they form two bipolar
transistors, one npn and one pnp transistor. The base of each transistor
is connected to the collector of the other, forming a cross-coupled
thyristor-like combination (see also section 5.9.3).
As a current is applied to the base of one transistor, the current is
amplified by the transistor and provided as the base current of the
other one. If the product of the current gain of both transistors is
larger than unity, the current through both devices increases until the
series resistances of the circuit limits the current. Latchup therefore
results in excessive power dissipation and faulty logic levels in the
gates affected. In principle, this effect can be eliminated by
separating the n-type and p-type device. A more effective
and less space-consuming solution is the use of trenches, which block
the minority carrier flow. A deep and narrow trench is etched between
all n-type and p-type wells, passivated and refilled with an insulating layer. |
| MOSFET memory is an
important application of MOSFETs. Memory chips contain the largest
number of devices per unit area since the transistors are arranged in a
very dense regular structure. The generic structure of a memory chip is
shown in Figure 7.6.2. |
| Figure 7.6.2: | Arrangement of memory cells into an array |
| A two dimensional
array of memory cells, each containing a single bit, are connected
through a series of word lines and bit lines. One row of cells is
activated by changing the voltage on the corresponding word line. The
information is then stored in the cell by applying voltages to the bit
lines. During a read operation, the information is retrieved by sensing
the voltage on the bit lines with a sense amplifier. A possible
implementation of a static random access memory (SRAM) is shown in
Figure 7.6.3. |
| Figure 7.6.3: | Static random access memory (SRAM) using a six-transistor cell. |
| Each memory cell
consists of a flip-flop and the cells are accessed through two pass
transistors connected to the bit lines and controlled by the word line.
Depletion mode transistors are shown here as load devices. A common
alternate load is an amorphous silicon resistor. |
| A simpler cell leading to denser memory chips is the dynamic random access memory (DRAM) shown in Figure 7.6.4. |
| Figure 7.6.4: | Dynamic random access memory (DRAM) using a one-transistor cell. |
| The dynamic cell
contains only a single transistor and capacitor. The cell is called
dynamic since the information is stored as charge on the capacitor. This
charge slowly leaks away so that the cell needs to be refreshed
periodically. The reading process is also destructive since the storage
capacitor is discharged as a voltage is applied to the word line.
Therefore, one has to rewrite the information into all the cells of a
given row after reading a single cell from that row. Despite these
restrictions, dynamic memory chips represent the largest section of the
memory market. The advantage of a higher storage density outweighs all
other considerations. Process advances such as the use of a vertical
trench, have further increased the density of dynamic memory chips. |
| As an example we now consider the dynamic memory cell shown in Figure 7.6.5.
Shown are the top view and cross-sectional view. The figure illustrates
how compact the cell can be by using the gate as the word line of the
array and by using a trench capacitor. Also note that the drain of the
transistor and one side of the capacitor are merged into one n-type
region. The bit lines shown in the top view are placed next to the
transistor for clarity. Actual memory cells have the bit lines on top of
the transistors as shown in the cross-sectional view. More recent
memory cells even have the transistor buried in the trench together with
the capacitor. |
| Figure 7.6.5: | Dynamic
random access memory (DRAM) using a one-transistor cell. (a) top view
of four cells and (b) cross-sectional view of one cell. |
A critical issue when
scaling dynamic memory circuits is the capacitance of the storage
capacitor. Scaling of all dimensions would yield a smaller value of the
capacitor. However, larger arrays, made possible by scaling the device
size, require a larger capacitance. After all, the critical operation in
a dynamic memory is the read-out. During read-out, the memory capacitor
is connected to the bit line and the charge is now distributed between
the memory cell capacitance, the bit line capacitance and the parasitic
capacitance of all the devices connected to the bit line. The remaining
voltage on the bit line therefore depends on the ratio of the cell
capacitance to that of the bit line and connected elements. In large
memory chips the voltage would become unacceptably low if the memory
capacitance would be scaled down with all other device dimensions.
Instead the capacitance of the memory capacitor is kept almost constant
from one generation to the next at a value around 1 fF. This value
corresponds to the storage of 25,000 electrons at a voltage of 5 V and
results in a bit line voltage of a few millivolts.
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