Title: Shallow trench isolation structure
Abstract: Method for preventing sneakage in shallow trench isolation and STI structure thereof. A semiconductor substrate having a pad layer and a trench formed thereon is provided, followed by the formation of a doped first lining layer on the sidewall of the trench. A second lining layer is then formed on the doped first lining layer. Etching is then performed to remove parts of the first lining layer and the second lining layer so that the height of the first lining layer is lower than the second lining layer. A sacrificial layer is then formed on the pad layer and filling the trench. Diffusion is then carried out so that the doped ions in the first lining layer out-diffuse to the substrate and form diffuse regions outside the two bottom corners of the trench.
Patent Number: 6,958,521 Issued on 10/25/2005 to Chang, et al.
| Inventors:
|
Chang; Ming-Cheng (Taoyuan, TW);
Chen; Yi-Nan (Taipei, TW);
Lin; Jeng-Ping (Taoyuan, TW)
|
| Assignee:
|
Nanya Technology Corporation (Taoyuan, TW)
|
| Appl. No.:
|
639419 |
| Filed:
|
August 11, 2003 |
Foreign Application Priority Data
| May 05, 2003[TW] | 92112210 A |
| Current U.S. Class: |
257/510; 257/519 |
| Intern'l Class: |
H01L 029/00 |
| Field of Search: |
257/510,519
|
References Cited [Referenced By]
U.S. Patent Documents
| 4140558 | Feb., 1979 | Murphy et al.
| |
| 6096598 | Aug., 2000 | Furukawa et al.
| |
| Foreign Patent Documents |
| 02-230763 | Sep., 1990 | JP.
| |
| 359001 | May., 1999 | TW.
| |
| 395014 | Jun., 2000 | TW.
| |
| 426935 | Mar., 2001 | TW.
| |
Other References
Hong Xiao, Introduction to semiconductor manufacturing technology, Copyright
2001 by Prentice-Hall Inc., Upper Saddle River, New Jersey 07458.
|
Primary Examiner: Weiss; Howard
Attorney, Agent or Firm: Quintero Law Office
Claims
1. A shallow trench isolation structure, which prevents sneakage, comprising:
a semiconductor substrate;
a trench filled with dielectric material, formed in the semiconductor substrate;
and
a diffuse region, formed in the semiconductor substrate only around bottom corners
of the trench.
2. The structure as claimed in claim 1, wherein the dielectric layer is oxide.
Description
BACKGROUND OF THE INVENTION
1. Field of the Invention
The present invention relates to a semiconductor process and in particular to
a method for preventing sneakage in shallow trench isolation (STI) and structure thereof.
2. Description of the Related Art
The trend in developing semiconductor devices with smaller size and higher integration
density has resulted in reduced distance between transistors. Shallow trench isolation
(STI) is currently the most widely applied method isolating transistors. It has
replaced the conventional method of local oxidation of silicon (LOCOS) to satisfy
the requirements for generations less than 0.18 microns.
FIG. 1 is a cross section of a conventional STI structure,
14 represents
a gate,
12 is an STI area, and n+ represents doped regions at two sides
of the STI
12. Turning on a passing wordline (not shown) causes leakage
of electric charge stored in the memory cell, a condition known as sneakage which
is shown as
10 in the figure. This adversely affects performance of semiconductor
elements. One current method of solving the above problem is forming STIs with
deeper trenches. As trench depth shrinks, however, filling the trenches becomes
more difficult.
Another method is implanting the sidewall of a trench to avoid formation
of leaking passages therein. FIGS.
2A˜
2C illustrate cross sections
of the above-mentioned method. A semiconductor
16 having a nitride layer
20 and an oxide layer
18 formed thereon is provided, as shown in
FIG. 2A. A photoresist layer
22 is used to define an isolation region, followed
by etching to form a trench
24, shown in FIG.
2B. The sidewall of
the trench is then implanted to form the implantation region
28, shown in
FIG.
2C. Formation of a leaking passage on the sidewall is thus prevented.
Finally, silicon oxide
26 is filled in the trench to form a shallow trench
isolation structure.
The shortcoming of the above-mentioned method is damage caused to the semiconductor
substrate during implantation. Hence, there is a need for a better method of avoiding
sneakage in shallow trench isolation structures.
SUMMARY OF THE INVENTION
Accordingly, an object of the invention is to provide a method that
prevents sneakage in shallow isolation trench structures.
The method for preventing sneakage in shallow trench isolation comprises the
steps of: providing a semiconductor substrate having a pad stack layer and a trench
formed therein; forming a doped first lining layer conformally on the sidewall
of the trench; forming a second lining layer conformally on the doped first lining
layer; etching the first lining layer and the second lining layer so that the height
of the first lining layer is lower than the second lining layer; forming a sacrificial
layer on the pad layer and filling the trench; subjecting the first lining layer
to diffusion so that the doped ions in the first lining layer out-diffuse to the
substrate and form diffuse regions at two bottom corners of the trench.
According to another embodiment of the invention, the method includes the
steps of: providing a semiconductor substrate having a pad stack layer and a trench
formed therein; forming a doped first lining layer conformally on the sidewall
and the bottom of the trench; forming a second lining layer covering the doped
first lining layer on the sidewall of the trench; etching the first lining layer
and the second lining layer so that the height of the first lining layer is lower
than the second lining layer; forming a sacrificial layer on the pad layer and
filling the trench; subjecting the first lining layer to diffusion so that the
doped ions in the first lining layer out-diffuse to the substrate and form a diffuse
region outside the bottom of the trench partially extending to the sidewall of
the trench.
According to the method provided in the invention, an STI structure without
sneakage comprises: a semiconductor substrate; a trench filled with dielectric
material, formed in the semiconductor substrate; and a diffuse region, formed in
the semiconductor substrate around the two bottom corners of the trench.
A detailed description is given in the following embodiments with reference to
the accompanying drawings.
BRIEF DESCRIPTION OF THE DRAWINGS
The present invention can be more fully understood by reading the subsequent
detailed description and examples with references made to the accompanying drawings, wherein:
FIG. 1 is cross section of a conventional STI structure;
FIG. 2A˜2C are cross sections showing the process of implanting
sidewall of a STI structure;
FIG. 3A˜3H are cross sections showing the process according
to the first embodiment of the invention;
FIG. 4A˜4F are cross sections showing the process according
to the second embodiment of the invention.
DETAILED DESCRIPTION OF THE INVENTION
First Embodiment
FIGS.
3A˜
3H are cross sections showing the method for preventing
sneakage in shallow trench isolation according to the First Embodiment of the invention.
As shown in FIG. 3A, a semiconductor
100 having a trench
130 and
a pad stack layer (including a nitride layer
120 and an oxide layer
110)
formed therein is provided. Next, as shown in FIG. 3B, a doped first lining layer
140A is formed conformally to cover the nitride layer
120, the sidewall
and bottom of the trench
130. Anisotropic etching, such as reactive ion
etching (RIE) is then performed to remove the first lining layer
140A on
the nitride layer
120 and the bottom of the trench
130 to form a
first lining layer
140B, as shown in FIG.
3C. The doped first lining
layer is preferably boron silicon glass (BSG).
Then, as shown in FIG. 3D, a second lining layer
150A is formed conformally
to cover the nitride layer
120, the sidewall and bottom of the trench, followed
by anisotropic etching, such as RIE or plasma etching to remove the second lining
layer on the nitride layer
120 and the bottom of the trench. A second lining
layer
150B is thus formed. The second lining layer is preferably non-doped
silicon glass (NSG).
Next, etching is carried out to remove portions of the first lining layer
140B
and the second lining layer
150B to form the second lining layer
150C
and the first lining layer
140C as shown in FIG.
3F. The height of
the second lining layer
150 is greater than that of the first lining layer
140C, i.e. the first lining layer only remains at the bottom corners of
the trench. In this step, etching is carried out by using etching solutions where
the etching rate of the BSG is greater than that of the NSG. Therefore, the first
lining layer
140C is lower than the second lining layer
150C.
Preferably the etching solution for this invention is buffered hydrogen
fluoride (BHF), wherein the ratio of NH
4F:HF:H
2O is preferably
5:1:48. Etching rates for NSG and BSG are 1200 angstroms/min and 7000 angstroms/min
respectively. Another preferable etching solution is ammonium hydrogen peroxide
mixture (APM) at 65° C., wherein the ratio of NH
4OH:H
2O
2:H
2O
is preferably 1:1:5. Etching rates for NSG and BSG are 5 angstroms/min and 200
angstroms/min respectively.
Next, as shown in FIG. 3F, a sacrificial layer
160, preferably non-doped
glass (NSG) is formed to fill the trench and cover the nitride layer
120.
The sacrificial layer is preferably formed by plasma enhanced chemical vapor deposition
(PECVD). Then, as shown in FIG. 3G, Boron ions doped in the first lining layer
140C out-diffuse to the substrate, as denoted by
165, to form a diffuse
region
170, as shown in FIG.
3H. Out-diffusion of the boron ions
is preferably carried out by a thermal annealing treatment. Preferable annealing
temperature and time are 900˜1000° C., and 15˜40 sec respectively.
Then, isotropic etching (using AMP at 60° C.) is used to remove the sacrificial
layer
160, the first lining layer
140C and the second lining layer
150C. The conventional method is then performed to form a dielectric layer
180 of silicon oxide, which fills the trench, by a method such as high density
plasma. Chemical mechanical polishing (CMP) is then carried out to polish the surface
of the dielectric layer to obtain a shallow trench isolation structure as illustrated
in the figure.
The shallow trench isolation structure obtained, comprises a semiconductor
100,
a trench filled with dielectric material
160, and diffuse regions
170
around the bottom corners of the trench, shown in FIG.
3H. Since the diffuse
regions
170 containing opposite charges with respect to the N+ regions on
two sides of the trench, are formed outside the bottom corners of the trench in
the semiconductor substrate, sneakage in STI is eliminated as leaking passages
around the trench have been prevented.
Second Embodiment
FIGS.
4A˜
4F are cross sections showing the process according
to the Second Embodiment of the invention.
As shown in FIG. 4A, a semiconductor
200 having a trench
230 and
a pad stack layer (includes a nitride layer
220 and an oxide layer
210)
formed thereon is provided. Next, as shown in FIG. 4B, a doped first lining layer
240A is formed conformally to cover the nitride layer
220 and the
sidewall and the bottom of the trench
230. Isotropic etching, using solution
such as APM at 60° C. is then performed to remove the first lining layer
240A
on the nitride layer
220 and the bottom of the trench
230 to form
a first lining layer
240B. The doped first lining layer is preferably boron
silicon glass (BSG).
Then, as shown in FIG. 4B, a second lining layer
250A is formed conformally
to cover the nitride layer
220 and the sidewall and the bottom of the trench,
followed by removing the second lining layer on the nitride layer
220 and
at the bottom of the trench. A second lining layer
250B, as shown in FIG.
4C, is thus formed. The second lining layer is preferably non-doped silicon glass (NSG).
Next, etching is carried out to remove portions of the first lining layer
240B
and the second lining layer
250B to form the second lining layer
250C
and the first lining layer
240C as shown in FIG.
4D. The height of
the second lining layer
250 is greater than that of the first lining layer
240C, i.e. the first lining layer remains at the bottom and corners of the
trench. In this step, etching is carried out by using etching solutions with a
faster etching rate for BSG than NSG. Therefore, the first lining layer
240C
is lower than the second lining layer
250C.
The preferable etching solution for this invention is buffered hydrogen fluoride
(BHF), wherein the ratio of NH
4F:HF:H
2O is preferably 5:1:48.
Etching rates for NSG and BSG are 1200 angstroms/min and 7000 angstroms/min respectively.
Another preferably etching solution is ammonium hydrogen peroxide mixture (APM)
at 65° C., wherein the ratio of NH
4OH:H
2O
2:H
2O
is preferably 1:1:5. Etching rates for NSG and BSG are 5 angstroms/min and 200
angstroms/min respectively.
Next, as shown in FIG. 4D, a sacrificial layer
260, preferably non-doped
glass (NSG) is formed to fill the trench and to cover the nitride layer
220.
The sacrificial layer
260 is preferably formed by plasma enhanced chemical
vapor deposition (PECVD). Then, as shown in FIG. 4E, Boron ions in the first lining
layer
240C out-diffuse to the substrate, as denoted by
265, to form
a diffuse region
270, as shown in FIG.
4F. Out-diffusion of the boron
ions is preferably carried out by a thermal annealing treatment. Preferably the
annealing treatment is carried out for 30 sec˜5 min at a temperature of 800˜1000° C.
Then, isotropic etching (using AMP at 60° C.) is carried out to remove
the sacrificial layer
260, the first lining layer
240C, and the second
lining layer
250C. The conventional method is then performed to form a dielectric
layer
280 of silicon oxide, which fills the trench, by a method such as
high density plasma. Chemical mechanical polishing (CMP) is then carried out to
polish the surface of the dielectric layer to obtain a shallow trench isolation
structure as illustrated in the figure.
The shallow trench isolation structure obtained, comprising a semiconductor
200,
a trench filled with dielectric material
260, and diffuse regions
270
around the bottom corners of the trench, is shown in FIG.
4F. Since the
diffuse region
270, containing opposite charges with respect to the N+ regions
on two sides of the trench, are formed outside the bottom corners of the trench
in the semiconductor, sneakage at STI is effectively inhibited.
According to the method for preventing sneakage in shallow trench isolation,
an ion doped region is formed either outside the bottom corners of the trench or
extending along the bottom in the semiconductor substrate. By doing so, the capacitive
STI transistors are more difficult to turn on, thereby avoiding sneakage current
in the STI structure. Performance of semiconductor elements is thus improved.
While the invention has been described by way of example and in terms of the
preferred embodiments, it is to be understood that the invention is not limited
to the disclosed embodiments. To the contrary, it is intended to cover various
modifications and similar arrangements (as would be apparent to those skilled in
the art). Therefore, the scope of the appended claims should be accorded the broadest
interpretation so as to encompass all such modifications and similar arrangements.
*
