Active solid-state devices (e.g. – transistors – solid-state diode – Field effect device – Having insulated electrode
Reexamination Certificate
2001-01-12
2002-06-11
Nelms, David (Department: 2818)
Active solid-state devices (e.g., transistors, solid-state diode
Field effect device
Having insulated electrode
C257S393000, C257S903000, C257S327000, C257S401000, C438S152000
Reexamination Certificate
active
06404023
ABSTRACT:
BACKGROUND OF THE INVENTION
1. Field of the Invention
The present invention relates to a semiconductor device and a method of fabricating the same. More particularly, the present invention relates to a semiconductor device including a static random access memory (SRAM) and a method of fabricating the same.
2. Description of Related Art
An SRAM is one type of semiconductor memory device and does not need refreshing. Therefore, the SRAM enables system configuration to be simplified and consumes only a small amount of current in await mode. Because of this, the SRAM is suitably used as a memory for portable devices such as a portable telephone in which the number of parts is limited and the power consumption therefor is required to be small.
The SRAM generally stores information using a flip-flop formed of two inverters, each having a load transistor and a driver transistor. The flip-flop is formed by connecting the gate electrode of one inverter to the drain of the other inverter. Specifically, the flip-flop is formed by cross-coupling one inverter with the other.
At present, miniaturization of portable devices is strongly demanded. As a means to achieve such a demand, miniaturization of memory cells of the SRAM has been demanded. For example, miniaturization of an SRAM by forming a flip-flop using two layers has been attempted.
In the case of forming a flip-flop using two layers, a layer for connecting the drains of each inverters and a layer for connecting the drain and the gate of the inverter can be cross-coupled by forming these layers as one conductive layer. According to this structure, such a conductive layer is formed over the regions including a region in which the drain of one inverter is formed, a region in which the gate of the other inverter is formed, and a region which connects these regions. Therefore, the conductive layer has a pattern with three ends (for example, a pattern having a branched portion in the shape of the letters “T” or “h”), or a spiral pattern in which the arms are intricate. For example, a pattern having a branched portion in the shape of the letter “T” is disclosed by Japanese Patent Application Laid-open No. 10-41409 in FIG. 1. A pattern with a branched portion in the shape of the letter “T” is also disclosed by M. Ishida, et. al. in
International Electron Devices Meeting Technical Digest
, 1998, page 203, FIG. 4(b). An example of a spiral pattern also can be seen in this
International Electron Devices Meeting Technical Digest
, page 203, FIG. 3(b).
However, in the case of SRAMs having such patterns, since the flip-flop is formed using two layers, the patterns of each layer are complicated. Therefore, it is difficult to reproduce the shape of a minute pattern in a photoetching step with high accuracy, whereby a desired pattern cannot be obtained. This hinders miniaturization of the memory size.
SUMMARY OF THE INVENTION
An objective of the present invention is to provide a semiconductor device having memory cells with a reduced size.
Another objective of the present invention is to provide a method of fabricating a more miniaturized semiconductor device.
According to a first aspect of the present invention, there is provided a semiconductor device comprising:
a memory cell portion having memory cells each of which includes two load transistors, two driver transistors, and two access transistors; and
a peripheral circuit portion which includes MOS transistors, wherein:
each of the memory cells includes first and second gate-gate connecting layers, first and second drain-drain connecting layers, and first and second drain-gate connecting layers;
the first and second gate-gate connecting layers are formed over a semiconductor substrate;
the first and second drain-drain connecting layers are formed over a first interlayer dielectric and connect drains of the load transistors with drains of the driver transistors;
the first and second drain-gate connecting layers are formed over a second interlayer dielectric;
the first drain-gate connecting layer connects the first drain-drain connecting layer to the second gate-gate connecting layer;
the second drain-gate connecting layer connects the second drain-drain connecting layer to the first gate-gate connecting layer;
the first and second gate-gate connecting layers, the first and second drain-drain connecting layers, and the first and second drain-gate connecting layers are provided in different layers at different levels;
the peripheral circuit portion has the first interlayer dielectric, the second interlayer dielectric, and a first wiring layer formed over the second interlayer dielectric; and
the first and second drain-gate connecting layers and the first wiring layer are formed in a layer at the same level.
The peripheral circuit portion includes circuits and others which are formed around the memory cell portion, for controlling or driving the memory cell portion or for operating with the memory cell. As examples of the peripheral circuit portion, an address decoder, sense amplifier, address buffer, control circuit, microcomputers such as an MCU or MPU, and the like can be given.
According to the semiconductor device of the present invention, the first and second gate-gate connecting layers are formed over the semiconductor substrate, the first and second drain-drain connecting layers are formed over the first interlayer dielectric, and the first and second drain-gate connecting layers are formed over the second interlayer dielectric, wherein a flip-flop is formed in the memory cell by these three layers. Therefore, the patterns of these layers can be simplified in comparison with a case of forming a flip-flop using two layers, thereby achieving miniaturization of the semiconductor device.
In the present invention, the term “formed in a layer at the same level” mainly means that the layers are formed in the same step. According to this configuration, the drain-gate connecting layers and the first wiring layer are formed in a layer at the same level in the same step, thereby reducing production costs.
Each of the memory cells may include an upper wiring layer formed over a third interlayer dielectric; the peripheral circuit portion may include the third interlayer and a second wiring layer formed over the third interlayer dielectric; and the upper wiring layer and the second wiring layer may be formed in a layer at the same level. This configuration can further increase the above effects. In this case, the upper wiring layer may be used as a bitline wiring layer.
The semiconductor device of the present invention has modifications as follows.
(1) Each of the first and second drain-drain connecting layers may have a thickness of 50-200 nm and a sheet resistance of 50 &OHgr;/□ or less. According to this configuration, a drain-drain connecting layer having a thickness and resistance appropriate to the use of the device can be obtained. If the drain-drain connecting layers have the above thickness, the focus margin can be increased when patterning the drain-drain connecting layers. This increases the wiring density and yield of the drain-drain connecting layers.
(2) The semiconductor memory device may further comprise first contact portions formed in the first interlayer dielectric, second contact portions formed in the second interlayer dielectric, and third contact portions formed through the first interlayer dielectric and second interlayer dielectric. If there are provided the third contact portions, it is not necessary to form connecting layers which connect the first contact portions to the second contact portions. Therefore, in a minute region, a degree of freedom relating to the location of the contact portions can be ensured by forming the third contact portions, thereby enabling the memory size to be reduced.
In this modification, the first and second gate-gate connecting layers may be connected to the first and second drain-drain connecting layers by the first contact portions.
Moreover, the first and second gate-gate connecting layers may be connected to the first and second drain
Kasuya Yoshikazu
Kawahara Kei
Mori Katsumi
Ho Tu-Tu
Nelms David
Oliff & Berridg,e PLC
Seiko Epson Corporation
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