Semiconductor device manufacturing: process – Making field effect device having pair of active regions... – Having insulated gate
Reexamination Certificate
2001-07-06
2003-02-11
Meier, Stephen D. (Department: 2822)
Semiconductor device manufacturing: process
Making field effect device having pair of active regions...
Having insulated gate
C438S213000
Reexamination Certificate
active
06518112
ABSTRACT:
BACKGROUND OF THE INVENTION
1. Field of the Invention
The present invention is related to integrated circuit (IC) chips and more particularly, to IC chips with CMOS SRAM cells and logic.
2. Background Description
Integrated circuit (IC) chip developers' primary goals are faster, denser, lower power IC chips. Typical, state of the art IC chips are manufactured, currently, in the complementary insulated gate Field Effect Transistor (FET) technology, commonly referred to as CMOS. Normally, each generation of CMOS technology is identified by its minimum feature size, e.g. “half micron CMOS” or “quarter micron CMOS”. Reducing the minimum feature size is the usual approach to making CMOS chips faster and denser simultaneously with reducing power.
Since the active area (channel region) of any given circuit amounts to less than 10% of the entire area of the circuit, designers are acutely aware that, no matter how small a circuit is, circuit area may still be reduced. However, reducing feature size alone may lead to problems that require other, non-geometric solutions, such as enhanced circuit wiring layers. Even using these state of the art non-geometric enhancements, circuit area reduction falls far short of 90%.
Reducing inactive area in an individual logic gate might have an insignificant impact on overall chip density. By contrast, reducing cell size in a Random Access Memory (RAM) array translates to a corresponding chip density improvement.
However, benefits from reducing RAM cell area are often offset by increased radiation sensitivity. Even Static RAM (SRAM) cells become sensitive at some point to alpha particle or cosmic ray radiation. While these effects are exacerbated by reduced SRAM operating voltages, they may be offset by adding selected process features, such as selective cell node capacitance enhancement and increased cell wiring resistance. Unfortunately, these additional features increase SRAM cell size and write time.
Consequently, designers have resorted to other approaches to reducing cell and circuit area, such as vertical devices, e.g., U.S. Pat. No. 5,414,289 to Fitch et al. entitled “Dynamic Memory Device Having a Vertical Transistor”.
Fitch et al. teaches opening a hole through a conductor layer (the gate) that is sandwiched by two dielectric layers. A thin dielectric layer (gate oxide) is grown on the sides of the gate conductor layer in the hole. This gate oxide layer is a rough indicator of when channel growth should begin and when it should end. Consequently, of Fitch et al.'s vertical FETs have substantial gate-drain and gate-source overlap with its associated overlap capacitance, which may be undesirable. This overlap capacitance is part of circuit load capacitance and contributes to other performance problems, such as Miller Effects.
CMOS circuit power is largely a function of supply voltage (V
h
), circuit load capacitance (C
L
) and operating frequency (i.e., chip clock frequency f
clk
). The general CMOS circuit power (P) formula is P=C
L
V
h
2
f
clk
. Thus, improving performance (increasing f
clk
) and reducing power, requires reducing either C
L
or V
h
or both.
Although, with each feature size reduction, usually, there has been a corresponding reduction in V
h
, this has not been the case with C
L
. Furthermore, as feature size shrinks, wiring resistance (i.e., per unit line resistance) increases, increasing RC propagation delays, which offsets some performance gains.
Thus, there is a need for CMOS technologies with reduced power supply voltage levels, reduced parasitic capacitance and wiring per unit length resistance, as well as reduced critical CMOS device parameters, such as channel length.
SUMMARY OF THE INVENTION
It is a purpose of the invention to improve FET channel length control.
It is a goal of this invention to reduce FET channel length variations.
It is another purpose of the present invention to improve CMOS logic and SRAM cell performance.
It is yet another purpose of the present invention to improve SRAM cell radiation hardness without degrading cell performance.
It is yet another purpose of the present invention to simultaneously achieve high speed and high density CMOS logic circuits, at low power dissipation levels.
The present invention is a vertical Field Effect Transistor (FET) that may be an N-type FET (NFET) or a P-type FET (PFET), a multi-device vertical structure that may be two or more NFETs or two or more PFETs, logic gates including at least one vertical FET or at least one multi-device vertical structure, a Static Random Access Memory (SRAM) cell and array including at least one vertical FET, a memory array including at least one such SRAM cell and the process of forming the vertical FET structure, the vertical multi-device structure, the logic gates and the SRAM cell.
The preferred vertical FETs are epitaxially grown layered stacks of NPN (for a NFET) or PNP (for a PFET). The side of a gate layer, preferably polysilicon, adjacent channel layer(s) in the stack is the gate of the device. The preferred multi-FET structure may be formed from the same channel layer by forming sides of two or more gates or, by stacking multiple channel layers in the same stack, e.g., PNPNP or NPNPN, each channel layer with its own gate, i.e., the side of a polysilicon gate layer. Two of these preferred multi-FET structures may be combined to form a CMOS logic gate by connecting together one end of each stack and connecting corresponding gates together. The preferred SRAM cell, made from the preferred embodiment FETs, may be radiation hardened by selectively thickening gate layers to increase storage node capacitance, providing high resistance cell wiring, including a multi-layered gate oxide layer of NO or ONO, or by any combination thereof.
REFERENCES:
patent: 3761782 (1973-09-01), Youmans
patent: 3884733 (1975-05-01), Bean
patent: 3986196 (1976-10-01), Decker et al.
patent: 4296428 (1981-10-01), Haraszti
patent: 4462040 (1984-07-01), Ho et al.
patent: 4466173 (1984-08-01), Baliga
patent: 4507674 (1985-03-01), Gaalema
patent: 4530149 (1985-07-01), Jastrzebski et al.
patent: 4554570 (1985-11-01), Jastrzebski et al.
patent: 4566025 (1986-01-01), Jastrzebski et al.
patent: 4624004 (1986-11-01), Calviello
patent: 4675717 (1987-06-01), Herrero et al.
patent: 4692791 (1987-09-01), Bayraktaroglu
patent: 4767722 (1988-08-01), Blanchard
patent: 4794093 (1988-12-01), Tong et al.
patent: 4807022 (1989-02-01), Kazior et al.
patent: 4810906 (1989-03-01), Shah et al.
patent: 4889832 (1989-12-01), Chatterjee
patent: 4927784 (1990-05-01), Kazior et al.
patent: 4951102 (1990-08-01), Beitman et al.
patent: 4956687 (1990-09-01), de Bruin et al.
patent: 4982266 (1991-01-01), Chatterjee
patent: 5001526 (1991-03-01), Gotou
patent: 5021845 (1991-06-01), Hashimoto
patent: 5027189 (1991-06-01), Shannon et al.
patent: 5032529 (1991-07-01), Beitman et al.
patent: 5034347 (1991-07-01), Kakihana
patent: 5057450 (1991-10-01), Bronner et al.
patent: 5063177 (1991-11-01), Geller et al.
patent: 5072276 (1991-12-01), Malhi et al.
patent: 5134448 (1992-07-01), Johnsen et al.
patent: 5252849 (1993-10-01), Fitch et al.
patent: 5292686 (1994-03-01), Riley et al.
patent: 5293053 (1994-03-01), Malhi et al.
patent: 5322816 (1994-06-01), Pinter
patent: 5343071 (1994-08-01), Kazior et al.
patent: 5354711 (1994-10-01), Heitzmann et al.
patent: 5414288 (1995-05-01), Fitch et al.
patent: 5414289 (1995-05-01), Fitch et al.
patent: 5449930 (1995-09-01), Zhou
patent: 5455064 (1995-10-01), Chou et al.
patent: 5528080 (1996-06-01), Goldstein
patent: 5719409 (1998-02-01), Singh et al.
patent: 6274904 (2001-08-01), Tihanyi
patent: 6392271 (2002-05-01), Alavi et al.
patent: 0552445 (1993-07-01), None
patent: 60-233911 (1985-11-01), None
M.E. Kcker, Interconnecting Monolithic Circuit Elements, IBM Technical Disclosure Bulletin, vol. 10 No. 7, Dec. 1967, p. 883.
E.I. Alessandrini & R.B. Laibowitz, Epitaxial Double-Sided Circuitry, IBM Technical Disclosure Bulleting, vol. 25 No. 10, Mar. 1983, pp. 5043-5044.
R.R. Garnache, Complimentary Fet Memory Cell, IBM Technical Disc
Armacost Michael D.
Bertin Claude L.
Hedberg Erik L.
Mandelman Jack A.
Chadurjian Mark F.
Meier Stephen D.
Whitham, Curtis & Christofferson
LandOfFree
High performance, low power vertical integrated CMOS devices does not yet have a rating. At this time, there are no reviews or comments for this patent.
If you have personal experience with High performance, low power vertical integrated CMOS devices, we encourage you to share that experience with our LandOfFree.com community. Your opinion is very important and High performance, low power vertical integrated CMOS devices will most certainly appreciate the feedback.
Profile ID: LFUS-PAI-O-3146230