Method for producing an EEPROM memory cell with a trench capacitor
First Claim
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1. A method for fabricating an EEPROM memory cell having a trench capacitor, which comprises:
- providing a substrate having a weakly doped epitaxial layer and a more heavily doped layer disposed under the weakly doped epitaxial layer;
forming a trench in the substrate, the trench having a lower region and an upper region, the lower region at least partially in the weakly doped epitaxial layer;
filling the lower region of the trench with a first filling material;
forming an insulation collar in the upper region of the trench;
removing the first filling material from the lower region of the trench;
forming a buried plate as a first capacitor plate in the lower region of the trench in the weakly doped epitaxial layer;
filling the trench with a conductive second filling material to form a second capacitor plate;
providing a capacitor dielectric between the conductive second filling material and the buried plate;
forming a dielectric tunnel layer in the trench at an interface of a buried contact and an associated selection transistor; and
forming a conductive protective layer on the dielectric tunnel layer.
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Abstract
The present invention provides a method for fabricating an EEPROM memory cell having a trench capacitor, having the following steps: formation of a trench (108) in a substrate (101); formation of a buried plate (165) in the substrate region in the vicinity of the lower region of the trench (108); concerted fabrication of a floating gate surrounded by dielectric layers in order to define the EEPROM region; optional recessing of the dielectric layer in order to define DRAM regions.
100 Citations
10 Claims
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1. A method for fabricating an EEPROM memory cell having a trench capacitor, which comprises:
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providing a substrate having a weakly doped epitaxial layer and a more heavily doped layer disposed under the weakly doped epitaxial layer;
forming a trench in the substrate, the trench having a lower region and an upper region, the lower region at least partially in the weakly doped epitaxial layer;
filling the lower region of the trench with a first filling material;
forming an insulation collar in the upper region of the trench;
removing the first filling material from the lower region of the trench;
forming a buried plate as a first capacitor plate in the lower region of the trench in the weakly doped epitaxial layer;
filling the trench with a conductive second filling material to form a second capacitor plate;
providing a capacitor dielectric between the conductive second filling material and the buried plate;
forming a dielectric tunnel layer in the trench at an interface of a buried contact and an associated selection transistor; and
forming a conductive protective layer on the dielectric tunnel layer. - View Dependent Claims (2, 3, 4, 5, 6, 7, 8, 9, 10)
removing the conductive second filling material and the insulation collar in the upper region of the trench to uncover the buried contact with the associated selection transistor;
carrying out the tunnel layer forming step by applying the dielectric tunnel layer on the interface of the buried contact and the conductive second filling material;
carrying out the protective layer forming step by applying the conductive protective layer on the tunnel layer; and
anisotropically etching the conductive protective layer and the tunnel layer resulting in the removal of the protective layer and the tunnel layer from the conductive second filling material, with the protective layer and the tunnel layer remaining in a region of the interface of the buried contact and the conductive second filling material.
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5. The method according to claim 3, which further comprises:
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removing the conductive second filling material and the insulation collar in the upper region of the trench to uncover the buried contact with the associated selection transistor;
carrying out the tunnel layer forming step by applying the dielectric tunnel layer on the interface of the buried contact and the conductive second filling material;
carrying out the protective layer forming step by applying the conductive protective layer on the tunnel layer; and
anisotropically etching the conductive protective layer and the tunnel layer resulting in the removal of the protective layer and the tunnel layer from the conductive second filling material with the protective layer and the tunnel layer remaining in a region of the interface of the buried contact and the conductive second filling material.
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6. The method according to claim 4, which further comprises:
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after the anisotropic etching, forming a strap above the insulation collar and on the conductive second filling material to the protective layer, the strap being made from a conductive third filling material;
planarizing and sinking the strap; and
forming an STI trench in the upper portion of the trench for insulating the EEPROM cell from other cells in an EEPROM matrix and for preventing strap formation between adjacent capacitors.
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7. The method according to claim 5, which further comprises:
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after the anisotropic etching, forming a strap above the insulation collar and on the conductive second filling material to the protective layer, the strap being made from a conductive third filling material;
planarizing and sinking the strap; and
forming an STI trench in the upper portion of the trench for insulating the EEPROM cell from other cells in an EEPROM matrix and for preventing strap formation between adjacent capacitors.
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8. The method according to claim 6, wherein the second and third conductive filling material is polysilicon.
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9. The method according to claim 7, wherein the second and third conductive filling material is polysilicon.
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10. The method according to claim 6, which further comprises recessing the dielectric tunnel layer to define DRAM regions.
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