Active solid-state devices (e.g. – transistors – solid-state diode – Field effect device – Having insulated electrode
Reexamination Certificate
1998-12-31
2001-11-13
Prenty, Mark V. (Department: 2822)
Active solid-state devices (e.g., transistors, solid-state diode
Field effect device
Having insulated electrode
C257S343000
Reexamination Certificate
active
06316807
ABSTRACT:
FIELD OF THE INVENTION
The invention relates in general to lateral semiconductor devices including a trench structure, and a method of manufacturing such devices. More specifically, the invention relates to MISFETs with a high breakdown voltage and a low on-resistance, which can be incorporated in integrated circuits, power supplies, motors and other devices.
BACKGROUND OF THE INVENTION
An example of one type of conventional high voltage lateral MISFETs with low on-resistance characteristics is shown in
FIG. 1. A
high resistive n
−
extended drain
10
is formed in a p
−
substrate
8
between a p base region
12
and an n
+
drain region
14
to reduce an electric field between a source region
16
and the drain region
14
. A gate oxide layer
18
under a gate electrode
20
is thicker at the drain side in order to reduce electric field in the n
−
extended drain
10
. Generally, lateral MISFETs consist of the following four regions shown in FIG.
1
: (1) a source region with a distance of 1
1
, (2) a channel region with a distance of 1
2
, (3) an extended drain region with a distance of 1
3
, and (4) a drain region with a distance of 1
4
. The pitch of the device is the sum of 1
1
+1
2
,+1
3
+1
4
and determines the packing density of the device and its specific on-resistance. The smaller the pitch, the higher the packing density and the lower the on-resistance per unit am& Present state of the art MISFETs with a breakdown voltage of 80 V require
13
to be 3 gm to reduce the electric field near the drain and prevent premature breakdown. The remaining parameters (1
1
, 1
2
, and 1
4
) do not influence the breakdown voltage significantly and are required to be 1.5 &mgr;m, 2 &mgr;m, and 1.5 &mgr;m respectively for 1
1
, 1
2
and 1
4
(for a 1 &mgr;m design rule). Thus, the distance or length of the n
−
extended drain
10
is the largest among all of the regions and must be increased as the breakdown voltage of the MISFET increases. As a result, the packing density of the MISFET is sacrificed and on-resistance increases. MISFETS with the above-described structure have already been described. See, for example, T. Efland, et al., “Self-Aligned RESURF To LOCOS Region LDMOS Characterization shows Excellent Rsp vs BV Performance” Proceedings ISPSD'96, pp. 147-150, 1996, the contents of which are incorporated herein by reference.
Results of on-state simulations performed for the structure shown in
FIG. 1
with a substrate doping level of 7×10
14
cm
3
, an n
−
extended drain surface doping concentration of 7×10
17
cm
3
and a junction depth of 1.4 &mgr;m are illustrated in FIG.
2
. For such simulations, the specific on-resistance of the device is estimated to be 1.6 m&OHgr;-cm
2
for a breakdown voltage of 80 V.
To overcome the packing density limitation discussed above, MISFETs using trench structures have been proposed by N. Fujishima, et al. in U.S. patent application Ser. No. 08/547,910. As illustrated in
FIG. 3
, a channel
24
and an n
−
extended drain
26
are located vertically at a side-wall of a trench formed in a substrate
28
. Since the trench MISFET has the n
−
extended drain
26
between a source region
31
and a drain region
32
, and a thick gate oxide
34
between a gate electrode
36
and the drain region
32
, it is possible to optimize the structure to get almost the same current handling capability in the unit cell as the conventional MISFET without reducing the breakdown voltage. The pitch in this case is determined by the sum of 1
1
, 1
6
, and 1
5
, which typically have values of 1.5 &mgr;m, 2.0 &mgr;m and 0.5 &mgr;m respectively (for minimum 1 &mgr;m design rules) resulting in half the pitch of the structure in FIG.
1
. Therefore, packing density per unit area of the MISFET can be increased and a reduction in on-resistance per unit area achieved.
However, for the device of
FIG. 3
, two additional masks are needed to define the silicon trench and the drain contact holes. The resulting process also requires strict alignment tolerance among these three masks. In addition, two deep directional etching steps are needed to define the gate and make the drain contact hole inside the initial silicon trench.
In view of the above, it is an object of the present invention to provide a lateral MISFET incorporating a high packing density trench structure and offering high breakdown voltage with low on-resistance and a method of manufacturing the lateral MISFET.
SUMMARY OF THE INVENTION
The present invention provides a semiconductor device incorporating a trench structure that combines high breakdown voltage with low on-resistance characteristics and a method for manufacturing the same. In a first embodiment, a Trench Lateral Power MISFET (T-LPM) is provided having a gate and channel regions that are built on the side-wall of the trench. The process used to form the T-LPM uses self-aligned trench bottom contact holes to contact a drain at the bottom of the trench to achieve minimum pitch and very low on-resistance. An example of a T-LPM with 80 V breakdown voltage having a cell pitch of four microns is disclosed in which an on-resistance of 0.8 m&OHgr;-cm
2
is realized.
More specifically, a semiconductor device is provided that includes a substrate of a first conductivity type having a trench formed therein that extends from a top surface of the substrate to a defined depth into the substrate. A dielectric material is formed on sidewalls of the trench, wherein a thickness of the dielectric material at the bottom of the trench is greater than a thickness of the dielectric material at the top of the trench. A contact hole extends through the dielectric material at the bottom of the trench to the substrate. A region of a second conductivity type is formed in the substrate beneath the contact hole, and an electrical interconnection material is formed in the trench that extends from the top of the trench through the contact hole to contact the region of second conductivity type.
In the first embodiment a MISFET is provided in which a base region of the first conductivity type is formed near a surface region of the substrate adjacent to the trench, and a source region is formed at the surface of the substrate above the base region. A first conductivity type diffusion region that extends from portions of the lower side walls and bottom of the trench, and a second conductivity type extended drain region is formed in said first conductivity type diffusion region. The region of second conductivity type formed under said contact hole is located in the extended drain region. A gate is located in the trench and is separated from the side walls of the trench and the electrical interconnection material by the dielectric material.
Process steps for forming the first embodiment include:
a) forming a trench in a substrate of first conductivity type;
b) growing a pad oxide in the trench;
c) depositing a nitride layer and etching the nitride layer to leave residual nitride layers that extend from the top of the trench and along the side walls of the trench;
d) extending the depth of the trench into the substrate;
e) depositing a thick oxide layer on the top of the substrate, the portions of the sidewall of the trench not covered by the residual nitride layer and the bottom of the trench;
f) removing the residual nitride layer and pad oxide and forming a gate oxide layer on the portions of the side walls that were previously covered by the residual nitride layer;
g) forming a gate layer on the gate oxide layer;
h) forming an oxide layer over the gate layer;
i) selectively etching the oxide layer formed over the gate layer, the thick oxide layer and the gate layer so that the surface of the substrate is exposed in regions adjacent to the trench and residual films of the gate layer and the thick oxide are left at the side-walls of the trench;
j) forming an oxide layer inside the trench and on the surface of the substrate by a method where oxide growth rate is slower inside the trench than at the surfac
Fujishima Naoto
Salama C. Andre T.
Prenty Mark V.
Rossi & Associates
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