Abstract: A method for growing a dielectric layer on a substrate, in accordance with the present invention, includes the steps of providing a substrate having at least two crystallographic planes which experience different dielectric layer growth rates due to the at least two crystallographic planes. A first dielectric layer is grown on the at least two crystallographic planes such that the first dielectric layer has a first thickness on a first crystallographic plane and a second thickness on a second crystallographic plane. The first thickness is thicker than the second thickness for the first dielectric layer. Dopants are implanted through the first dielectric layer. A greater number of dopants are implanted in the substrate through the second thickness than through the first thickness of the first dielectric layer. The first dielectric layer is then removed. A second dielectric layer is grown at a same location as the removed first dielectric layer.

Abstract: A method for ion implantation of high dielectric constant materials with dopants to improve sidewall stoichiometry is disclosed. Particularly, the invention relates to ion implantation of (Ba,Sr)TiO3 (BST) with Ti dopants. The invention also relates to varying the ion implantation angle of the dopant to uniformly dope the high dielectric constant materials when they have been fabricated over a stepped structure. Additionally, the invention relates to forming a capping layer over a horizontal portion of the BST film to reduce excess dopant from being implanted into the horizontal section of the BST film. The invention also relates to integrated circuits having a thin film high dielectric material with improved sidewall stoichiometry used as an insulating layer in a capacitor structure.

Abstract: A process of forming a hybrid memory cell which is scalable to a minimum feature size, F, of about 60 nm at an operating voltage of Vblh of about 1.5 V and substantially free of floating-well effects is provided.

Abstract: Methods of preparing dual workfunction high-performance support metal oxide semiconductor field effect transistor (MOSFETs)/embedded dynamic random access (EDRAM) arrays are provided. The methods describe herein reduce the number of deep-UV masks used in the forming memory structure, decouple the support and arraying processing steps, provide salicided gates, source/drain regions and bitlines, and provide, in some instances, local interconnects at no additional processing costs. Dual workfunction high-performance support MOSFETs/ EDRAM arrays having a gate conductor guard ring and/or local interconnections are also provided.

Abstract: The present invention provides a method for making the bottom electrode of a buried capacitor, which is characterized by protecting the non-bottom electrode region with a LPD oxide layer to prevent the impurities within the doped Si glass remaining in non-bottom electrode region from driving into the substrate during annealing, thus non-desired diffusing region connecting to the bottom electrode will be generated. Consequently, the leakage current existing in conventional buried capacitor will be effectively reduced according to the method of this present invention.

Abstract: A method for fabricating deep-submicron vertically arranged capacitors is disclosed which allows the capacitor to enjoy an enhanced sidewall surface so as to attain a capacitance of 40 pF or more.

Abstract: The present invention relates to a method of forming a trench-type capacitor. More particularly, the plate areas of the trench-type capacitor are increased according to the present invention.

Abstract: A method of fabricating a trench cell capacitor can be used in the formation of a DRAM cell. In one embodiment, a trench is formed within a semiconductor substrate. The trench is lined with a dielectric layer, e.g., an ONO layer. After lining the trench, a collar is formed in an upper portion of the trench by forming an oxide layer in the upper portion. A nitride layer on the oxide layer. The trench is then filled with semiconductor material. For example, a semiconductor region can be epitaxially grown to fill the trench.

Abstract: A method and structure for manufacturing an integrated circuit device includes forming a storage device in a substrate, lithographically forming a gate opening in the substrate over the storage device, forming first spacers in the gate opening, forming a strap opening in the substrate using the first spacers to align the strap opening, forming second spacers in the strap opening, forming an isolation opening in the substrate using the second spacers to align the isolation opening, filling the isolation opening with an isolation material, removing the first spacers and a portion of the second spacers to form a step in the gate opening, (wherein the second spacers comprise at least one conductive strap electrically connected to the storage device) forming a first diffusion region in the substrate adjacent the conductive strap, forming a gate insulator layer over the substrate and the step, forming a gate conductor over a portion of the gate insulator layer above the step, forming a second diffusion region in th

Abstract: A method of forming a DRAM capacitor. A hemispherical grain structure is formed on the surface of the bottom electrode of the capacitor. By employing an additional annealing under a dopant contained ambient, the dopant is diffused into the hemispherical grain structure and distributed at the surface area of the hemispherical grain region.

Abstract: A method of fabricating a lower electrode of a capacitor. A sacrificial multilayer is formed on a semiconductor layer. The sacrificial multi-layer is a stack of alternating first and second sacrificial layers. A patterned first mask layer having a first opening above a conductive plug in the semiconductor substrate is formed on the sacrificial multi-layer. A planar spacer is formed on the sidewall of the first opening. A second mask layer is formed to fill the first opening. The planar spacer and the sacrificial multi-layer thereunder are anisotropically etched until the semiconductor substrate is exposed to form a second opening while using the first mask layer and second mask layer as a mask. The first sacrificial layers exposed by the second opening are isotropically etched to form a plurality of recesses. The second opening and the recesses are filled with a conductive material layer. Finally, the first mask layer, second mask layer, and sacrificial multi-layer are removed.

Abstract: A method for forming a trench capacitor of a dynamic random access memory cell is disclosed. The method includes patterning to etch a semiconductor substrate (10) of a first conductivity to form a trench (18) in the substrate. Ions of the first conductivity are tilt-implanted over the trench, so that sidewalls and a bottom surface of the substrate near the trench are doped with the ions of the first conductivity. Next, first ions of a second conductivity are tilt-implanted over the trench at a first angle, thereby forming a first implanted region (22), followed by tilt-implanting second ions of the second conductivity over the trench at a second angle, thereby forming a second implanted region (24). The first angle is larger than the second angle, and the first implanted region and the second implanted region together form a bottom cell plate of the trench capacitor.

Abstract: A semiconductor device includes a semiconductor substrate having a trench on a surface thereof and an embedding member embedding the interior of the trench therewith. While the section of the trench when cut by a first plane perpendicular to the direction of the depth of the trench is defined as a first section and the section of the trench when cut by a second plane perpendicular to the direction of the depth of the trench and closer to the bottom of the trench than the first plane is defined as a second section, the area of the first section is smaller than that of the second section and a minimum radius of curvature of the first section is smaller than a minimum radius of curvature of the second section. As a result, it is possible to lessen the concentration of the electric field into the bottom of the trench.

Abstract: To reduce a junction leakage of an junction interface between a P type well portion formed on a P type substrate and a source region, an impurity region of a first conductive type or a second conductivity type is formed at the junction interface. A plug ion is implanted in the source region to increase a depletion depth of the source region and a counter doping is then performed in the source region to reduce an electrical field of the source region.

Abstract: Reduced variations in buried layer across the chip is provided. The reduction in variation is achieved by defining the top surface of the buried layer and then the lower surface of the buried layer. This results in improved control buried strap variations, thereby improving performance of the IC.

Abstract: A method for planarizing the surface of a semiconductor device which employs spin on glass (SOG) and an etching operation to remove high portions of the SOG prior to a chemical metal polish (CMP) operation. The SOG is baked and cured before etching. Additional layers of SOG and etching operations may be employed as necessary. A thick encapsulating oxide layer is deposited over the SOG layer. For surface irregularities caused by metal lines, an insulating layer may be deposited over the surface before the SOG. Where an additional metal line is to be deposited on the surface, an additional insulating layer is deposited after the CMP operation. In the case of metal lines made of aluminum, provision is also made for preventing Hillock formations on the metal lines.

Abstract: A MOS device and method of fabricating the same, wherein the source/drain region has polysilicon trench structure which are formed by self-alignment using silicon oxide layers as masks. The source/drain regions extend to the field oxide layer and/or above the gate. Therefore, contacts can be formed on source/drain conductive regions above the field oxide layer.

Abstract: A trench of a buried plate type DRAM has a bottom portion wider than an opening portion. A silicon oxide film is formed on an upper portion of the side wall of the trench. An N-type impurity diffusion region is formed around the bottom portion of the trench. Impurity diffusion regions of adjacent trenches are integrally connected with each other as one portion. A first polycrystalline silicon layer is formed on the impurity diffusion region in the trench and the silicon oxide film. The polycrystalline silicon layer is coated with a laminated film consisting of a silicon nitride film and a silicon oxide film. The trench is filled with a second polycrystalline silicon layer covering the laminated film. The impurity diffusion region serves as a plate diffusion region of a capacitor, the first polycrystalline silicon layer serves as a plate electrode, the laminated film serves as a capacitor insulating film, and the second polycrystalline silicon layer serves as a storage node electrode.

Abstract: A method of fabricating a semiconductor device comprising a step of forming a trench selectively on a semiconductor substrate, a step of positioning said semiconductor substrate to a first position inclined to a plane vertical to ion beams, a step of injecting ions by emitting ion beams to a side-wall of the trench of the semiconductor substrate at the first position, a step of positioning said semiconductor substrate to a second position which is different from the first position by rotating it, and a step of injecting ions by emitting ion beams to a side-wall of the trench of the semiconductor substrate at the second position.