Active solid-state devices (e.g. – transistors – solid-state diode – Field effect device – Having insulated electrode
Reexamination Certificate
1999-09-07
2001-02-20
Carroll, J. (Department: 2811)
Active solid-state devices (e.g., transistors, solid-state diode
Field effect device
Having insulated electrode
C257S344000, C257S369000, C257S371000, C257S391000, C257S392000, C438S231000, C438S232000, C438S279000
Reexamination Certificate
active
06191460
ABSTRACT:
BACKGROUND
1. Field of Invention
This invention relates to semiconductor integrated circuit memory devices, and more particularly to static random access memory (SRAM) devices in which some insulated gate transistors have N-type conductivity gates and other insulated gate transistors have P-type conductivity gates.
2. Related Art
Static random access memory (SEAM) cells using cross-connected complementary metal oxide semiconductor (CMOS) inverters are widely used.
FIG. 1
is a schematic drawing showing a typical prior art six transistor (6T) SRAM cell
2
. As shown, transistors N
1
, N
2
, N
3
, and N
4
are N-type MOS (NMOS) transistors and transistors P
1
and P
2
are P-type MOS (PMOS) transistors.
As shown, transistors P
1
and N
1
form inverter
10
. Transistor P
1
is coupled between a voltage source (not shown) supplying voltage V
DD
(typically 5.0 or 3.5 volts, although other voltages are possible, e.g., 2.5 volts) and node A. Transistor N
1
is coupled between node A and a second voltage source (not shown) supplying voltage V
SS
(typically a reference potential, e.g., ground). Similarly, transistor P
2
is coupled between V
DD
and node B, and transistor N
2
is coupled between node B and V
SS
. Inverters
10
and
12
are cross-connected such that node A is coupled to the gates of transistors P
2
and N
2
, and node B is coupled to the gates of transistors P
1
and N
1
. Thus if a logic low state, for example low voltage, exists at node A, transistor P
2
conducts and transistor N
2
does not conduct. The voltage at node B is therefore approximately V
DD
and a logic high state, for example high voltage, exists at node B. Due to the logic high state at node B, transistor P
1
does not conduct and transistor N
1
conducts. The voltage at node A is therefore approximately V
SS
and a logic low state exists at node A. Accordingly, the cross-connected inverter configuration is stable.
FIG. 1
also shows select transistor N
3
coupled between node A and bit line
14
, and select transistor N
4
coupled between node B and {overscore (bit)} line
16
. The gates of transistors N
3
and N
4
are each coupled to word line
18
. Of importance is that current flows in transistors P
1
and P
2
as nodes A and B, respectively, change logic state. Over time, and in large memory cell arrays, the cumulative current flows may be a significant factor in overall circuit power consumption.
FIG. 1
includes a conventional sensing circuit
20
and conventional control circuit
22
. Sensing circuit
20
is coupled to bit line
14
and {overscore (bit)} line
16
. Control circuit
22
is coupled to bit line
14
, {overscore (bit)} line
16
, and word line
18
. Persons skilled in the art will understand that circuits
20
and
22
provide voltage sources that control writing and reading of information stored as logic states in SRAM cell
2
. Circuits
20
and
22
typically contain both NMOS and PMOS transistors in a variety of conventional configurations.
In early 6T-SRAM integrated circuits the NMOS and PMOS transistors both in the memory cells, and in the control and sensing circuits, were formed with conductive polycrystalline silicon (polysilicon) gate electrodes (gates) heavily doped to N-type conductivity. Later, a “dual gate process” fabrication approach was used in which all NMOS transistors were formed with polysilicon gates having N-type conductivity and all PMOS transistors were formed with polysilicon gates having P-type conductivity. The dual gate process is typically used to form 3.3V and 2.5V technology SRAM integrated circuits. For example, PMOS transistors having P-type gates are typically used for sensing and control circuits, e.g., circuits
20
and
22
, in SRAM integrated circuits because their lower threshold voltage (V
T
), compared with PMOS transistors having N-type gates, and higher drain-source current (I
DS
) increases operating speed.
FIG. 2
is a simplified cross-sectional view showing a typical CMOS structure. (Note that the overlying passivation layers and source/drain/gate electrode contacts are not shown.) The NMOS and PMOS transistors of the type shown are typically used in, for example, memory cell
2
, sensing circuit
20
, and control circuit
22
(FIG.
1
). As shown, a conventional P-Well semiconductor area
30
(of P-type conductivity) and a conventional N-Well semiconductor area
32
(of N-type conductivity) are each formed in crystalline substrate
34
. Conventional field oxide layer
36
and conventional gate oxide layer
40
are each formed on substrate
34
's surface
38
as shown. Conductive gate
42
A is formed on oxide layer
40
above region
30
and conductive gate
42
B is formed on oxide layer
40
above region
32
. In single gate technology, gates
42
A and
42
B are typically heavily N-type (N+) doped polysilicon. For dual gate technology, gate
42
A is typically N+ polysilicon, and gate
42
B is typically heavily P-type (P+) doped polysilicon.
As shown, NMOS transistor
44
is formed with N+ regions
46
, and with lightly doped N-type (N−) regions
48
underlying conventional sidewall spacers
50
as shown. The N+ regions
46
are approximately aligned (self-aligned) with spacers
50
as shown. The N− regions
48
are approximately aligned (self-aligned) with gate
42
A. Also shown is PMOS transistor
52
formed with P+ regions
53
, and with lightly doped P-type (P−) regions
54
underlying spacers
50
as shown. The P+ regions
53
are approximately aligned (self-aligned) with spacers
50
as shown. The P− regions
54
are approximately aligned (self-aligned) with gate
42
B as shown. Persons skilled in the art will be familiar with various conventional fabrication methods used to form transistors
44
and
52
.
Stability is the ability of a memory cell to retain its programmed state; SRAM cell stability is desirable. In 6T SRAMs, e.g., SRAM cell
2
, memory cell stability is enhanced by reducing I
DS
in the pull-up PMOS load transistors when these transistors conduct. One method of reducing I
DS
is to make the PMOS transistor “weaker” or less conductive. One way of making the PMOS weaker is to lightly dope source and/or drain regions.
U.S. Pat. No. 5,804,477 ('477 Patent), under common assignment with the present invention and incorporated herein by reference, discloses “a 6-T SRAM cell which occupies less chip area, [and] has improved write speed and improved latch-up immunity.” See U.S. Pat. No. 5,804,477, col. 3 line 66. In the '477 patent a MOS transistor is made weaker by omitting heavily doped portions of source/drain regions. As described in detail in the '477 patent, lightly doped source and/or drain regions provide increased resistance with a consequent I
DS
decrease and enhanced SRAM stability.
The '477 patent further discloses a range of dopant concentration ratios between source/drain regions and the substrate region in which the source/drain regions are formed. For example, referring to
FIG. 2
, if N-Well
32
has a particular dopant concentration, and if the P− source/drain regions
54
comprised the entire source/drain regions, the P− regions
54
would have a dopant concentration of 1 to 2.5 times the particular dopant concentration of N-Well
32
. Such a range of ratios also applies to NMOS transistors formed in P-wells.
Although the '477 patent demonstrates lowered I
DS
and improved stability over previously known 6T SRAMs, further I
DS
reductions and enhanced memory cell stability are desirable. Improved stability is especially important in low voltage memory cells, such as those operating at approximately 2.5 volts.
SUMMARY
In accordance with the invention, the dual gate process is modified so that both NMOS and PMOS memory cell transistors have gates of the same conductivity type. As in conventional SRAM integrated circuits, the associated NMOS sensing and control circuit transistors have N-type gates and the associated PMOS sensing and control circuit transistors have P-type gates. However,
Choi Jeong Y.
Lien Chuen-Der
Carroll J.
Integrated Device Technology Inc.
Skjerven Morrill MacPherson Franklin & Friel
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