Shallow trench filled with two or more dielectrics for isolation and coupling for stress control
First Claim
1. A method for fabricating a n+ to n+ capacitor, comprising:
- providing a stop layer on a substrate;
etching a plurality of trenches through said stop layer and into said substrate;
depositing a first layer over said stop layer and filling said trenches wherein said first layer comprises a dielectric material having a first dielectric constant;
planarizing said first layer to said stop layer leaving said first layer within said trenches;
thereafter removing said first layer from a subset of said trenches;
depositing a second layer over said stop layer and within said subset of trenches, wherein said second layer comprises a dielectric material having a second dielectric constant higher than said first dielectric constant;
planarizing said second layer to said stop layer leaving said second layer within said subset of trenches; and
forming n+ junctions on either side of one of said subset of trenches, wherein said one of said subset of trenches forms a capacitor dielectric of said n+ to n+ capacitor.
1 Assignment
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Accused Products
Abstract
A method for forming shallow trenches having different trench fill materials is described. A stop layer is provided on a substrate. A plurality of trenches is etched through the stop layer and into the substrate. A first layer is deposited over the stop layer and filling said trenches. The first layer is planarized to the stop layer leaving the first layer within the trenches. The first layer is removed from a subset of the trenches. A second layer is deposited over the stop layer and within the subset of trenches and planarized to the stop layer leaving the second layer within the subset of trenches to complete fabrication of shallow trenches having different trench fill materials. The trench fill materials may be dielectric layers having different dielectric constants or they may be a dielectric layer and a conducting layer. The method can be extended to provide three or more different trench fill materials.
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Citations
17 Claims
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1. A method for fabricating a n+ to n+ capacitor, comprising:
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providing a stop layer on a substrate; etching a plurality of trenches through said stop layer and into said substrate; depositing a first layer over said stop layer and filling said trenches wherein said first layer comprises a dielectric material having a first dielectric constant; planarizing said first layer to said stop layer leaving said first layer within said trenches; thereafter removing said first layer from a subset of said trenches; depositing a second layer over said stop layer and within said subset of trenches, wherein said second layer comprises a dielectric material having a second dielectric constant higher than said first dielectric constant; planarizing said second layer to said stop layer leaving said second layer within said subset of trenches; and forming n+ junctions on either side of one of said subset of trenches, wherein said one of said subset of trenches forms a capacitor dielectric of said n+ to n+ capacitor. - View Dependent Claims (2)
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3. A method for fabricating a p+ to p+ capacitor, comprising:
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forming an n-well within said substrate; providing a stop layer on a substrate;
etching a plurality of trenches through said slop layer and into said substrate;depositing a first layer over said stop layer and filling said trenches, wherein said first layer comprises a dielectric material having a first dielectric constant; planarizing said first layer to said stop layer leaving said first layer within said trenches; thereafter removing said first layer from a subset of said trenches; depositing a second layer over said stop layer and within said subset of trenches, wherein said second layer comprises a dielectric material having a second dielectric constant higher than said first dielectric constant; planarizing said second layer to said stop layer leaving said second layer within said subset of trenches; and forming p+ junctions within said n-well on either side of one of said subset of trenches, wherein said one of said trenches forms a capacitor dielectric for said p+ to p+ capacitor. - View Dependent Claims (4)
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5. A method for fabricating a vertical MOSFET, comprising:
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forming a deep n-well within a substrate; providing a stop layer on said substrate; etching a plurality of trenches through said stop layer and into said substrate; depositing a first layer over said stop layer and filling said trenches, wherein said first layer comprises a dielectric material having a first dielectric constant; planarizing said first layer to said stop layer leaving said first layer within said trenches; thereafter removing said first layer from a subset of said trenches; depositing a second layer over said stop layer and within said subset of trenches, wherein said second layer comprises a dielectric material having a second dielectric constant higher than said first dielectric constant; planarizing said second layer to said stop layer leaving said second layer within said subset of trenches; forming within said deep n-well a first n+ junction on one side of one of said subset of trenches, called a high-k trench, and forming a p-well underlying said first n+ junction, wherein said p-well forms the body of a vertical MOSFET device; and forming within said deep n-well a second gate n+ junction on another side of said high-k trench, wherein said second n+ junction is formed deeper than said first n+ junction and wherein a p-base is formed underlying said second n+ junction; wherein said vertical MOSFET device is turned on by forming an inversion layer at a sidewall of said body adjacent to said high-k trench.
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6. A method for fabricating a vertical MOSFET, comprising:
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providing a stop layer on a substrate; etching a plurality of trenches through said stop layer and into said substrate; depositing a first layer over said stop layer and filling said trenches, wherein said first layer comprises a dielectric material having a first dielectric constant; planarizing said first layer to said stop layer leaving said first layer within said trenches; thereafter removing said first layer form a subset of said trenches; depositing a second layer over said stop layer and within said subset of trenches, wherein said second layer comprises a dielectric material having a second dielectric constant higher than said first dielectric constant; planarizing said second layer to said stop layer leaving said second layer within said subset of trenches; forming a first p+ junction on one side of one of said trenches filled with said one of said first and second layers having said higher dielectric constant, called a high-k trench, and forming a n-well underlying said p+ junction, wherein said n-well forms the body of a vertical MOSFET device; and forming a second gate p+ junction on another side of said high-k trench, wherein said second n+ junction is formed deeper than said first p+ junction and a n-base is formed underlying said second p+ junction; wherein said vertical MOSFET device is turned on by forming an inversion layer at a sidewall of said body adjacent to said high-k trench.
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7. A method for fabricating a semiconductor device, comprising:
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providing a stop layer on a substrate; etching two first trenches and one second trench between the first trenches through said stop layer and into said substrate; forming a first layer in the first trenches wherein said first layer comprises a first dielectric material having a first dielectric constant; forming a second layer in the second trench, wherein said second layer comprises a second dielectric material having a second dielectric constant higher than said first dielectric constant; forming a first junction of a first conductivity type on one side of the second trench; and forming a second junction of said first conductivity type on another side of the second trench; wherein the first trenches and the second trench are filled with said first and second dielectric materials, respectively, and the first and second trenches do not comprise any electrically conductive material. - View Dependent Claims (8, 9, 10, 11, 12, 13, 14, 15, 16, 17)
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Specification