Active solid-state devices (e.g. – transistors – solid-state diode – Integrated circuit structure with electrically isolated... – Including dielectric isolation means
Reexamination Certificate
1998-09-10
2001-02-06
Abraham, Fetsum (Department: 2811)
Active solid-state devices (e.g., transistors, solid-state diode
Integrated circuit structure with electrically isolated...
Including dielectric isolation means
C257S336000, C257S344000, C257S374000, C257S408000, C257S367000, C257S368000, C257S900000, C438S221000, C438S218000, C438S294000, C438S296000
Reexamination Certificate
active
06184566
ABSTRACT:
BACKGROUND OF THE INVENTION
1. Field of the Invention
This invention relates to the field of semiconductor processing and more particularly to a method for isolating transistors after formation of the transistor devices.
2. Description of the Relevant Art
In a metal-oxide-semiconductor (MOS) integrated circuit, a plurality of transistors are fabricated within and upon a monolithic semiconductor substrate typically comprising of doped silicon. To effectively isolate individual transistors from one another so that the individual devices may be selectively interconnected to achieve a desired function, isolation structures must be included in the integrated circuit. In the absence of adequate isolation structures, an individual transistor could undesirably become electrically coupled to a neighboring transistor. Such undesirable and unpredictable coupling of transistors within a semiconductor can render the device non-functional.
Historically, the predominant MOS isolation method has been the local oxidation (LOCOS) process. In the LOCOS process, as is well known in the field of semiconductor processing, a relatively thick thermal oxide film is formed between the source/drain regions of neighboring transistor devices. The thermally grown oxide film, commonly referred to as the field oxide, consumes silicon within the silicon substrate surface such that the field oxide tends to form partially within and partially upon the silicon substrate. More specifically, approximately 45% of a field oxide film will extend into the silicon substrate while the remaining 55% grows above the silicon substrate upper surface. Field oxide formation is suppressed in regions of the silicon substrate wherein active devices will subsequently be formed by depositing a layer of silicon nitride over the active regions prior to the formation of the field oxide. The silicon nitride is typically deposited on a thin “pad” oxide to relieve the stress that silicon nitride films impart to a silicon surface. The thick field oxide film serves to isolate active regions displaced on either side of the field oxide film. To enhance the isolation capabilities of the field oxide, an implant is commonly performed to introduce impurities into a region under the field oxide. The polarity or conductivity type of the impurity introduced under the field oxide film is opposite the conductivity type of the subsequently formed source/drain regions.
Typical LOCOS field oxide films grow with a characteristic bird's beak structure that extends partially into the active regions of the neighboring transistors. This encroachment upon the transistor active region by the field oxide structure coupled with the portion of the field oxide that forms above the semiconductor substrate surface results in a non-planar surface upon which the transistors must be subsequently formed. As the geometries of semiconductor devices decrease below the sub 0.5 micron range, the planarity of the surface upon which transistors are formed becomes increasingly important. For example, short-channel effects (SCE), which can result in increased subthreshold leakage, can become exaggerated when transistors are formed upon a non-planar surface.
One method of improving the planarity of MOS isolation structures is the shallow trench isolation (STI) process. In an STI process, a trench is etched into the silicon substrate and subsequently filled with a dielectric material, typically an oxide. A planarization step is then performed to remove the oxide from regions exterior to the isolation trench. Ideally, the upper surface of the semiconductor substrate is completely planar after the planarization of the trench dielectric. Although the STI process is theoretically capable of producing a planar surface upon which transistors can be formed, significant processing is required to achieve the planar surface prior to the formation of the transistors. Specifically, it may be necessary to perform a number of chemical-mechanical polish steps, possibly in combination with some selective masking steps and some plasma etch steps to achieve the desired planarity. The incorporation of these processing steps prior to the formation of a gate dielectric is generally undesirable because of the increased potential for generating defects in critical regions of the silicon substrate and because of the high particle counts associated with these planarization processing steps.
In both the LOCOS process and the STI process, the isolation dielectric must be formed with an initial thickness substantially greater than the final desired thickness of the film. The additional film thickness is necessary because of the presence of subsequent processing steps that reduce the isolation dielectric thickness. More specifically, the typical transistor formation process includes cleaning and wafer preparation steps that require immersion in a 10:1 solution of HF. In addition, the incorporation of “spacer” structures into many MOS processes necessitates a spacer etch step. The HF dip process steps and spacer etch process step attack the isolation dielectric and reduce the isolation film thickness. Thus, the original film thickness must be increased to compensate for these film-reducing process steps. Since thicker films generally require more processing time, the need to overgrow or “over deposit” the isolation dielectric is an undesirable result. In addition, the numerous post-formation processing steps that attack the isolation dielectric make it more difficult to control the final film thickness. To accommodate the film thickness variations that can result because of the multiple processing steps that etch the isolation dielectric, the process specification must be relaxed. Generally, it is more desirable to have a narrow specified range for any given process parameter to reduce the variability in the operating characteristics of the finished product.
Therefore, it is desirable to implement a semiconductor process in which the gate dielectric and subsequent transistor formation processing steps are performed upon a planar silicon substrate without requiring a significant increase in the pre-transistor formation processing. It is further desirable to reduce or eliminate the number of oxide etch steps to which the isolation dielectric is subjected.
SUMMARY OF THE INVENTION
The problems identified above are in large part addressed by a semiconductor process in which the isolation structure is formed subsequent to the formation of the transistor devices. By delaying the formation of the isolation structure until after the transistor formation, the improved process hereof provides a planar surface upon which to form the transistors without requiring a significant increase in pre-transistor formation or “front end” processing. By providing a planar surface, the present invention enables the precise formation of submicron transistor regions. In addition, the improved process, by forming the isolation dielectric after transistor formation, reduces the amount by which the isolation dielectric must be formed in excess of the desired film thickness and reduces therewith the final film thickness variability.
Broadly speaking, the present invention contemplates a method for isolating semiconductor devices. A semiconductor substrate is provided having laterally displaced source/drain regions and channel regions. First and second MOS transistors are then formed, laterally displaced from one another, within the semiconductor substrate. The first and second transistors have a common source/drain region. An isolation trench is then formed through the common source/drain region. The trench is then filled with a dielectric material to divide the common source/drain region into electrically isolated first and second source/drain regions so that the first transistor is electrically isolated from the second transistor.
In a presently preferred embodiment, the formation of the laterally displaced first and second transistors comprises forming a gate dielectric layer on an upper surface of the semiconductor substrate, an
Fulford Jr. H. Jim
Gardner Mark I.
Hause Fred N.
Abraham Fetsum
Advanced Micro Devices , Inc.
Conley Rose & Tayon PC
Kowert Robert C.
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