This invention relates to wafers and substrates such as are used in micromechanical electrical system (MEMS) devices or semiconductor devices.
Device isolation typically is achieved by utilizing local oxidation of silicon (“LOCOS”) or shallow trench isolation (“STI”) techniques. In the STI device isolation technique, isolation is typically achieved by forming a recess or trench in a layer that is destined to become two adjacent active areas, and filling the trench with an isolation material. The material in the trench, typically a nitride material, is referred to as a spacer. Nitride spacers, in addition to electrical isolation, may also be used as a fluid barrier.
STI is beneficial in providing higher packing density, improved isolation, and greater planarity, by avoiding the topographical irregularities encountered when using conventional thick film oxide isolation (LOCOS). In particular, the growth of thermal field oxide using a mask, such as nitride, creates an encroachment of the oxide into the active areas; this encroachment is referred to as the bird's beak effect.
Isolation using STI, however, has some limitations. For example, there is a relatively short diffusion path along the junction of the spacer and the underlying substrate for fluids (gas and liquids). Accordingly, there is an increased potential for leakage. Additionally, because the spacer is deposited on the surface of the substrate layer, the spacer is susceptible to shear forces which can lead to leakage and even failure of the device at the junction of the spacer and the underlying substrate.
What is needed therefor is a plug and method of forming a plug that overcomes one or more problems in known plugs. It would be beneficial if the plug and method of forming a plug could increase the diffusion path past the plug. It would be further beneficial if the plug and method of forming a plug could increase the strength of the plug-to-substrate layer interface.
In one embodiment, a method of forming a plug includes providing a base layer, providing an intermediate oxide layer above an upper surface of the base layer, providing an upper layer above an upper surface of the intermediate oxide layer, etching a trench including a first trench portion extending through the upper layer, a second trench portion extending through the oxide layer, and a third trench portion extending into the base layer, depositing a first material portion within the third trench portion, depositing a second material portion within the second trench portion, and depositing a third material portion within the first trench portion.
In a further embodiment, A wafer includes a base layer, an intermediate oxide layer above an upper surface of the base layer, an upper layer above an upper surface of the intermediate oxide layer, a trench including a first trench portion extending through the upper layer, a second trench portion extending through the oxide layer, and a third trench portion extending only partially into the base layer, and a plug, the plug including a first material portion deposited within the third trench portion, a second material portion deposited within the second trench portion, and a third material portion deposited within the first trench portion.
For the purposes of promoting an understanding of the principles of the invention, reference will now be made to the embodiments illustrated in the drawings and described in the following written specification. It is understood that no limitation to the scope of the invention is thereby intended. It is further understood that the present invention includes any alterations and modifications to the illustrated embodiments and includes further applications of the principles of the invention as would normally occur to one skilled in the art to which this invention pertains.
The wafer 100 further includes a plug 108. The plug 108 extends from the upper surface of the wafer 100 completely through the upper layer 106 and the intermediate layer 104 while a recessed portion 110 extends partially into the substrate layer 102. The recessed portion 110 provides improved adhesion to the substrate layer 102. Additionally, the recessed portion 110 provides increased strength in that the ability of the plug 108 to withstand shear forces is a function of the material used to form the plug 108, and not just a function of a bond formed between the plug 108 and the substrate layer 102.
Additionally, the recessed portion 110 creates a tortuous path along the junction of the plug 108 and the substrate layer 102. Consequently, fluids such as air or liquid present in the intermediate layer 104 on one side of the plug 108 are effectively isolated from the portion of the intermediate layer 104 on the other side of the plug 108. Thus, a gap 112 in
A trench 128 is then etched through the upper layer 126, the intermediate layer 124, and partially into the substrate layer 122 as depicted in
In
The wafer 120 may then be further processed in any desired manner. In this embodiment, a portion of the intermediate layer 124 is selectively etched to create a gap 140 shown in
The procedure depicted in
The trench 158 may be etched in substantially the same manner as the trench 128 of
The trench 162 may be formed using an isotropic final silicon etch. The trench 162 includes a recessed portion 170 that includes expanded areas 172 and 174. The expanded areas 172 and 174 extend laterally within the substrate layer 152 to locations directly underneath an un-etched portion of the intermediate layer 154. The trench 162 further includes sidewall protecting layers 176 and 178. The sidewall protecting layers 176 and 178 prevent etching of the upper layer 156 during etching of the substrate layer 152.
Once the trenches 158, 160, and 162 have been formed, a plug material 180 is deposited in the trenches 158, 160, and 162 and on the upper surface of the upper layer 156 (see
In
The plug 186 includes a recessed portion 194 that includes expanded areas 196 and 198. The expanded areas 196 and 198 extend laterally within the substrate layer 152 to locations directly underneath an un-etched portion of the intermediate layer 154.
The wafer 150 may then be further processed in any desired manner. In this embodiment, portions of the intermediate layer 154 are selectively etched to create gaps 200 and 202 shown in
In addition to the expanded areas described above, a plug may be further modified to provide desired performance characteristics in a variety of manners. As depicted in
In addition to the increased stress resistance of the plugs described above, the plugs 244 and 246 provide resistance to separation of layers clamped by the plugs. Thus, plug 244 clamps the intermediate layers 236 and 238 together while the plug 246 clamps the intermediate layers 234, 236, 238, and 240 together. Accordingly, plugs as disclosed herein may be modified to incorporate a number of different enlarged areas to further maintain the integrity of a wafer.
While the invention has been illustrated and described in detail in the drawings and foregoing description, the same should be considered as illustrative and not restrictive in character. It is understood that only the preferred embodiments have been presented and that all changes, modifications and further applications that come within the spirit of the invention are desired to be protected.
This application claims the benefit of U.S. Provisional Application No. 61/475,457, filed on Apr. 14, 2011.
Number | Date | Country | |
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61475457 | Apr 2011 | US |