Semiconductor device manufacturing: process – Making field effect device having pair of active regions... – Having insulated gate
Reexamination Certificate
2000-04-07
2002-11-12
Nelms, David (Department: 2818)
Semiconductor device manufacturing: process
Making field effect device having pair of active regions...
Having insulated gate
C438S243000, C438S386000, C438S392000
Reexamination Certificate
active
06479346
ABSTRACT:
BACKGROUND OF THE INVENTION
1. Field of the Invention
The present invention relates to a semiconductor memory device, and in particular to a flash electrically erasable programmable read only memory (flash EEPROM) device and a fabrication method thereof.
2. Description of the Background Art
FIG. 1
illustrates a cell layout of a conventional semiconductor memory device.
A plurality of field oxide films
101
are formed on a semiconductor substrate
100
. The field oxide films
101
correspond to non-active regions or device isolation regions. The regions except for the field oxide films
101
are active regions
102
. A plurality of floating gates FG are formed vertically to the active regions
102
. An insulation film (not shown) is positioned on the floating gate FG, and a control gate CG is formed in an identical direction to the floating gate FG. In addition, a source
103
and a drain
104
are respectively formed on the active regions
202
at both sides of the floating gate FG. A contact hole
105
for connecting a bit line BL to the drain region
104
is formed at a predetermined region of the drain
104
. The bit line BL is positioned crossing the control gate CG, and connected to the drain
104
via the contact hole
105
. Referring to FIG.
1
, a dotted-lined inner structure provided with reference numeral
110
depicts a unit cell of a flash electrically erasable programmable read only memory (flash EEPROM).
FIG. 2
is a vertical-sectional view taken along Line II—II in
FIG. 1
, illustrating a unit cell of an ETOX (EPROM with Tunnel Oxide) type flash EEPROM. As shown therein, a tunnel oxide film
201
which is a gate oxide film of a floating gate is formed on a semiconductor substrate
200
. A floating gate electrode
202
consisting of polysilicon, an interpoly dielectric film
203
and a control gate electrode
204
are sequentially stacked on the tunnel oxide film
201
. A source
205
and a drain
206
are formed in the semiconductor substrate
200
at both sides of the floating gate electrode
202
. The source
205
includes a first source layer
205
a
(n+ layer) which is relatively highly doped, and a second source layer
205
b
(n− source) which is a relatively lightly doped. Such a source is called a graded junction source. The drain
206
is a highly-doped layer (n+ layer), identical to the first source
205
a.
The reason why the conventional flash EEPROM device employs the above asymmetric structure of the source (n−
+ structure) and the drain (p+
+ structure) will now be described.
During a programming operation of the flash EEPROM, a high voltage of 8V is applied to the drain, and a high voltage of 12V is applied to the gate electrode. A hot electron, generated in the drain, passes through the tunnel oxide film, and enters the floating gate. Accordingly, generation of the hot electron is facilitated by forming an abrupt junction of n+/p+ between the drain and substrate, thereby improving programming speed. In addition, a high voltage (over 10V) is applied to the source during an erase operation, thereby emitting the hot electron from the floating gate to the source. Here, in order for the source junction to endure the latter high voltage, a doping concentration of the n-type source is slowly decreased. The above-described flash memory cell has a disadvantage in that the cell's area is increased due to lateral diffusion of the source.
Accordingly, a method of applying a negative voltage to the gate electrode and applying a voltage below 5V to the source is conventionally practiced in order to restrict increase of the cell area resulting from the lateral diffusion and to improve reliability of the source junction. The flash memory of the aforementioned structure does not require a deep and slow junction structure (graded junction structure) like the ETOX memory as shown in FIG.
1
. Therefore, the increase of the cell area resulting from the lateral diffusion of the source can be restricted. However, an overlap between the floating gate and the source region is necessary during the erase operation. In addition, the doping concentration of the source region must be sufficiently high to prevent a voltage drop by the source voltage during the program operation. For example, when the source is formed, the doping is below 2*10
15
atom/cm
2
, a depletion layer is formed at an overlapping region with the floating gate. This results in tunneling, thereby sharply decreasing gate current. As a result, although the modified source structure does not require the graded junction structure, an asymmetric structure is formed where the source and drain have different doping concentrations.
Referring to
FIG. 3A
, a device isolation region
301
, namely a field oxide film
301
is formed on a semiconductor substrate
300
according to a wellknown partial silicon oxidation process. The regions, except for the field oxide films
301
are active regions
301
, and the regions of the field oxide films
302
are non-active regions. Here, the field oxide film is shown merely at the right side of
FIG. 3A
because the left side thereof illustrates the vertical-sectional view taken along Line IIIe—IIIe in FIG.
1
.
As illustrated in
FIG. 3A
, a tunneling oxide film
303
is formed at a predetermined region of the semiconductor substrate
300
where a flash memory cell unit will be formed. Thereafter, a first polysilicon layer is formed on the tunneling oxide film
303
, and patterned in order to remain merely at the active region
302
, thereby forming a first polysilicon layer pattern
304
. An interpoly dielectric film
305
consisting of an oxide film
itride film/oxide film structure (hereinafter, referred to as ‘ONO film’) is formed on the resultant structure of the semiconductor substrate
300
. The ONO film
305
serves to insulate the floating gate and the control gate, and becomes a gate insulation film of the control gate to be formed in a succeeding process. As shown at the right side of
FIG. 3A
, the ONO film
305
on the semiconductor substrate of the peripheral circuit unit is removed.
Then, a cleansing process is carried out. As illustrated at the right side of
FIG. 3B
, the entire surface of the semiconductor substrate is thermally oxidized, thereby forming a gate oxide film
306
on the semiconductor substrate
300
of the peripheral circuit unit.
As depicted in
FIG. 3B
, a second polysilicon layer is formed on the entire surface of the semiconductor substrate
300
. The second polysilicon layer, the ONO film
305
and the first polysilicon layer pattern
304
are etched by using a known stack gate etching process, thereby forming a second polysilicon layer pattern
307
a,
namely a control gate electrode
307
a,
and a floating gate electrode
304
a
which is self aligned with the control gate electrode
307
a,
patterned, and positioned therebelow. The floating gate electrode
304
a
is formed by patterning the first polysilicon layer pattern
304
according to the stack gate etching process. Here, referring to the right side of
FIG. 3B
, a gate electrode
307
b
is also formed by patterning the second polysilicon layer.
As shown at the right side of
FIG. 3C
, a first ion implantation mask
320
is formed on the semiconductor substrate of the peripheral circuit unit. As depicted at the left side of
FIG. 3C
, ions are implanted in order to form a source
308
and a drain
309
of the memory cell unit.
Thereafter, the first ion implantation mask
320
is removed. As shown at the left side of
FIG. 3D
, a second ion implantation mask
330
is formed on the semiconductor substrate of the memory cell unit, and as shown at the right side of
FIG. 3D
, impurity ions are implanted into the semiconductor substrate
300
at both sides of the gate electrode
307
b
of the peripheral circuit unit, thereby forming a lightly-doped region
310
which is called LDD.
The second ion implantation mask
330
is removed. As illustrated in
FIG. 3E
, sidewall spacers
311
are formed at both side walls of the floating
Lee Sung-Chul
Yi Sang-Bai
Yu Jae-Min
Berry Renee R.
LG Semicon Co. Ltd.
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