Active solid-state devices (e.g. – transistors – solid-state diode – Field effect device – Having insulated electrode
Reexamination Certificate
1998-01-27
2002-05-28
Loke, Steven (Department: 2811)
Active solid-state devices (e.g., transistors, solid-state diode
Field effect device
Having insulated electrode
C257S330000, C257S335000, C257S341000
Reexamination Certificate
active
06396102
ABSTRACT:
BACKGROUND OF THE INVENTION
1. Field of the Invention
The present invention relates to the field of power semiconductor devices. More particularly, the present invention relates to a semiconductor device employing double-diffused metal oxide semiconductor (DMOS) type technology used to construct field effect transistor (FET) devices. Moreover, the present invention relates to a structure which uses trench DMOS-FET technology to implement such devices. Still more particularly, the present invention provides for a re-designed gate signal bus, where MOS trenches are arranged in parallel formation to effect an electric field coupling between the trenches, resulting in a reduction of the peak electric field in the area around the gate signal bus.
2. Description of the Prior Art
MOS devices, particularly MOS field effect transistors (MOSFETs), represent a fundamental component of any contemporary electronic system. MOSFETs are distinguished from power MOSFETs in that power MOSFETs can dissipate more than 0.5 W and are physically larger than typical MOSFETs. Those power MOSFETs having a drain-to-source voltage of less than 150V are generally identified as low-voltage power MOSFETs and are typically used in “power management” applications. Such applications include, but are not limited to, power switches, switching regulators, and linear regulators. It is this type of power MOSFET that is the focus of the present invention.
One type of power MOSFET is a double-diffused-type FET sometimes called a DMOS transistor. DMOS transistor fabrication uses diffusion to form the transistor channel regions. A power MOSFET is essentially a large array of unit-cell DMOS transistors with several additional elements to evenly distribute gating signals and control device breakdown voltage. DMOS devices have the advantage of providing low-power dissipation and high-speed capability. Accordingly, DMOS technology is preferred in high-voltage circuitry of today's high-power integrated circuit applications. Applications in which such power MOSFETs utilizing DMOS technology are found range from high-voltage telecommunication circuits down to 3.3 volt DC—DC converters used on personal computers. Devices utilizing DMOS technology have been common throughout these applications for nearly 20 years. Many advances in DMOS technology regarding the device fabrication and device characteristics have also occurred during this period. Currently, power MOSFETs represent the third fastest growing market in the world. Performance gains are achieved by cell-density increases, which mean decreasing unit cell dimensions. As power MOSFETs are a high volume, competitive market, a premium is placed on manufacturing innovation leading to stable, low cost, and high-yielding production processes.
In the field of power MOSFET production, there have been a variety of other processes utilized. For production of the dominant device structure for DMOS power MOSFETS, there has existed the so called “planar process” of production. The planar process derives its name from the fact that the MOSFET channel and gating structures are co-planar with the silicon wafer surface. In
FIG. 1
, a prior-art DMOS structure is shown in the form of a planar DMOS structure
10
produced by the planar process. This planar structure is predominant in mainstream production of DMOS power MOSFETs. In
FIG. 1
, the DMOS structure
10
includes a channel
12
and a gating structure
13
. Both the channel
12
and gating structure
13
are co-planar to a silicon-wafer surface
11
. Although the planar process has been well refined over the years, it exhibits considerable scaling limitations. Such limitations are becoming particularly apparent when the planar process is scaled to small-cell dimensions. As performance gains in power MOSFETs are obtained by increasing cell density—and thus decreasing unit-cell dimensions—the limitations in the planar process approach for such planar DMOS devices appear far sooner than the equipment's photo lithographic limitations. This problem stems from the poly-silicon gate that is used to control the power MOSFET's channel characteristics. Basically, the gate dimension for a given junction depth cannot be reduced indefinitely without forcing the so-called JFET resistance term to become a dominating constituent of the device's overall ON-state resistance—a key parameter. The JFET resistance term gains its name from junction field effect transistor (JFET) operation and arises from the nature of the structural junctions between layers.
Concurrent with the development of the prior-art planar process described above, other technology has been developed with the goal of keeping the JFET resistance term from becoming a dominating constituent. More particularly, an emerging technology in power MOSFET production avoids the JFET problem by forming the device's channel along the sidewalls of an etch trench. This alternative prior-art design is shown in FIG.
2
and includes a trench DMOS structure
20
. The trench DMOS structure
20
includes a gate-channel
22
along the sidewalls
25
of a trench
24
beside gate
23
. This trench
24
is etched into the silicon wafer surface
21
so that the channel
22
is positioned perpendicular to the silicon wafer surface
21
. This type of production process is appropriately named “trench DMOS technology,” or simply “trench technology.” A benefit of this trench technology is that it virtually eliminates the JFET problem. This permits increases in cell density by orders of magnitude, the only limitation then being that imposed by the fabrication equipment.
In typical power MOSFET structures, the width of the depletion region determines the electric field that exists across the region and hence the voltage drop. Therefore, any applied voltage beyond this magnitude must be partially dropped across the thin gate oxide layer. If this becomes too great, hot electron generation can occur which can lead to irreversible device breakdown. Typically, this is alleviated by placing a thick layer (e.g., 8500 Å) of thermally grown silicon dioxide underneath the poly-silicon gate. This additional oxide layer is not inconsequential. It effectively represents one to three additional photomasking steps and a relatively long thermal cycle for its growth. In some cases, a thermal cycle upwards of nine hours is needed. Further, this additional oxide layer is commonly found to be a significant source of ionic contaminants. Such contamination can ultimately adversely influence the given device's reliability. The use of trench technology in the power MOSFET structure of the present invention eliminates the need for this additional oxide layer.
Trench technology has not heretofore been utilized to its fullest extent. One area in which trench technology has not been utilized is in power MOSFET bus architecture. Contemporary production power MOSFETs, using trench—or other—technology, require a thick field oxide layer beneath the poly-silicon gate bus structure to suppress hot electron injection. Other methods to address this problem include forming impurity junctions within the gate bus, which would also suggest a field-coupling mechanism. This, however, requires more area for the gate bus since holes must be etched into the poly-silicon bus to allow implanted ions into the silicon surface below. Furthermore, these junctions would be electrically floating and, hence, would not have a well-defined potential voltage. This can lead to dynamic performance degradation since bulk carriers near the junction can be modulated under certain bias conditions.
Accordingly, the prior art fails to provide any MOSFET bus architecture capable of efficient utilization of trench technology. Therefore, what is needed is a method of MOSFET device production that utilizes trench technology to redesign an element of that device—namely, the gate signal bus. What is needed is such MOSFET device production that results in the formation of a MOSFET bus structure capable of withstanding voltages up to the maximum v
Fairchild Semiconductor Corporation
Hu Shouxiang
Jaeckle Fleischmann & Mugel LLP
Loke Steven
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