Mask ROM, and fabrication method thereof

Active solid-state devices (e.g. – transistors – solid-state diode – Field effect device – Having insulated electrode

Reexamination Certificate

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Details Mask ROM, and fabrication method thereof Mask ROM, and fabrication method thereof

: 2001-11-07
: 2004-05-11
: Flynn, Nathan J. (Department: 2826)
: Active solid-state devices (e.g., transistors, solid-state diode
: Field effect device
: Having insulated electrode

: Reexamination Certificate
: active
: 06734508
: ABSTRACT:

CROSS REFERENCE TO RELATED APPLICATION
This application claims the priority of Korean patent application Serial No. 2001-51826 filed on Aug. 27, 2001.
BACKGROUND OF THE INVENTION
1. Field of the Invention
The present invention relates to a mask ROM and a fabrication method thereof, and in particular to a mask ROM which has excellent compatibility with a logic process and improves integration of a memory cell, and a fabrication method thereof.
2. Description of the Background Art
A mask ROM is a non-volatile device for discriminating data and recording necessary information according to a mask process in an element isolation process, a metal process or an ion implant process for a channel region of a memory cell.
FIG. 1
is a layout diagram illustrating a memory cell of a conventional flat cell type mask ROM.
The flat cell type mask ROM has been widely used in a fabrication method using a logic process.
Referring to
FIG. 1
, the flat cell type mask ROM includes: a substrate
100
where a memory cell array region I and a segment select region II are defined; a trench (not shown) formed at the outer portion of the memory cell array region I of the substrate
100
; an element isolating film (not shown) filling up the trench; a plurality of buried layers
110
aligned on the resultant structure in a first direction by a predetermined interval; and a plurality of gates
114
aligned in a second direction to cross the buried layers
110
in an orthogonal direction.
In the fabrication process of the flat cell type mask ROM, an isolation process is performed at the outer portion of the memory cell array region I to surround the whole memory cell array region I, instead of performing a LOCOS or STI process for isolating memory cells. A source/drain junction of the memory cell is the buried layer
110
formed before the gate process. It is thus unnecessary to isolate the junctions.
A contact
122
of the buried layer junction does not exist in the memory cell array region I but in the segment select region II. In addition, a width of the gate
114
is a channel width of the memory cell.
As described above, the isolating film and the contact are not formed in the memory cell, and thus a size of the memory cell is about 4F
2
(‘F’ implies a minimum line width of photolithography), thereby improving integration, simplifying the whole process and cutting down production costs.
When a logic process of a design rule below 0.35 &mgr;m is applied to the fabrication process of the flat cell type mask ROM, 1) the isolation process is performed by LOCOS, 2) N type impurity-doped polysilicon, Ti-Salicide or W-Polycide is used as the gate formation material, and 3) Ti-Salicide identical to the gate formation material is employed as the source/drain junction.
In addition, when the flat cell type mask ROM is fabricated according to a logic process of a design rule below 0.25 &mgr;m, 1) the isolation process is performed to surround the whole memory cell array region by a trench STI, 2) Ti-Salicide or Co-Salicide is used as the gate formation material, and 3) Ti-Salicide or Co-Salicide identical to the gate formation material is employed as the source/drain junction.
Accordingly, the flat cell type mask ROM having compatibility with the logic process of a design rule below 0.35 &mgr;m has been commercially used. There are therefore increasing demands for a flat cell process having compatibility with the logic process below 0.25 &mgr;m.
FIG. 2
is a flowchart showing a conventional flat cell type mask ROM process.
As illustrated in
FIG. 2
, the conventional method for fabricating the mask ROM includes: an isolation process for forming an element isolating film at the outer portion of a memory cell array region; a well formation process; a buried layer formation process; a process for forming a gate insulating film and gates in the memory cell array region and its peripheral region; a cell isolation ion implant process for implanting ions to the memory cell array region; a process for forming a source/drain in the gates of the peripheral region; a coding process; a process for forming a contact in a buried layer of a segment select region; and a bit line formation process.
FIGS. 3
a
through
3
c
are cross-sectional diagrams, taken along lines AB, BC and CD of FIG.
1
. In
FIGS. 3
a
to
3
c
, ‘a’ denotes an active region of the memory cell array region, and ‘b’ denotes a peripheral region which is the outer portion of the active region.
The conventional method for fabricating the mask ROM will now be described in detail with reference to
FIGS. 3
a
to
3
c.
As depicted in
FIG. 3
a
, provided is a substrate
100
where a memory cell array region I and a segment select region II are defined.
A trench
103
is formed by etching the outer portion of the active region (a) of the memory cell array region I of the substrate
100
. Thereafter, an insulating film such as an oxide silicon film is deposited over the resultant structure, and etched according to an etch back process or a chemical mechanical polishing process, to form an element isolating film
104
filling up the trench
103
.
A well
102
is formed on the substrate
100
having the element isolating film
104
according to an impurity implant process. Here, the element isolating film formation process may be performed after the well formation process, as depicted in FIG.
3
B.
Thereafter, a photolithography process and an impurity implant process are sequentially carried out in the memory cell array region I and the segment select region II of the substrate
100
having the well
102
, thereby forming buried layers
110
,
111
aligned in one direction.
A gate insulating layer
112
is positioned on the substrate
100
, to form gates
114
aligned in an orthogonal direction to the buried layers
110
,
111
.
Although not illustrated, a cell isolation ion implant process is performed in the active region (a) of the memory cell array region I, a source/drain
130
is formed in the peripheral region (b), and a coding process is performed thereon.
As shown in
FIG. 3
c
, a protective film
120
is deposited on the substrate
100
, and a contact
122
serving as a passage to a bit line (not shown) to be formed according to a succeeding process is formed on the buried layer
111
of the segment select region II.
Then, the bit line electrically connected to the buried layer
111
of the segment select region II through the contact
122
is formed, and thus fabrication of the mask ROM is finished.
When the mask ROM is fabricated according to the logic process of a design rule below 0.25 &mgr;m, the element isolating film is formed according to the shallow trench isolation and the chemical mechanical polishing process.
In general, one segment of the memory cell consists of 32 word lines and 1024 bit lines. When a size of the segment is decreased, an area of the memory cell having the same integration is increased. Considering that the gate is designed under the minimum design rule, a height of the 32 word lines is approximately 64F. When it is presumed that a height of the segment select end is about 12F, a height of the segment is 76F, and a length of the 1024 bit lines is about 2048F. That is, a size of the segment is represented by ‘2048F×76F’. In the case of the design rule below 0.25 &mgr;m, the size of the segment is represented by ‘512F×19 &mgr;m’.
The memory cell is an aggregate of the segments. For example, 128 segments are required to compose a 4M bit memory cell array. Therefore, a size of the 4M bit memory cell is approximately ‘512F×2432 &mgr;m’, which is a size of the active region composing a memory cell block.
However, in the conventional method for fabricating the mask ROM, a polishing speed is not uniform in the wide active region of the memory cell array region. As a result, polishing uniformity is reduced in a memory cell larger than ‘200 &mgr;m×200 &mgr;m’.
In addition, the buried layer is patterned in a minimum size allowable in the photolithography. It is thus difficult to pattern the buried layer in the

Affiliated with

Lim Min Gyu

Inventor

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Dongbu Electronics Co. Ltd.

Corporate Assignee

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Flynn Nathan J.

Examiner

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Keefer Timothy J.

Attorney

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Quinto Kevin

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Seyfarth Shaw LLP

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