Abstract: In one embodiment, the present invention relates to a method of forming a silicon oxynitride antireflection coating over a metal layer, involving the steps of providing a semiconductor substrate comprising the metal layer over at least part of the semiconductor substrate; depositing a silicon oxynitride layer over the metal layer having a thickness from about 100 Å to about 150 Å; and forming an oxide layer having a thickness from about 5 Å to about 50 Å over the silicon oxynitride layer to provide the silicon oxynitride antireflection coating.

Abstract: In one embodiment, the present invention relates to a method of forming a silicon oxynitride antireflection coating over a metal layer, involving the steps of providing a semiconductor substrate comprising the metal layer over at least part of the semiconductor substrate; depositing a silicon oxynitride layer over the metal layer having a thickness from about 100 Å to about 1500 Å; and forming an oxide layer having a thickness from about 5 Å to about 50 Å over the silicon oxynitride layer to provide the silicon oxynitride antireflection coating.

Abstract: A method and system for providing a semiconductor device is disclosed. The method and system include providing a semiconductor substrate and providing a plurality of lines separated by a plurality of spaces. Each of the plurality of spaces preferably has a first width that is less than a minimum feature size. In one aspect, the method and system include providing a reverse mask having a plurality of apertures on an insulating layer. In this aspect, the method and system also include trimming the reverse mask to increase a size of each of the plurality of apertures, removing a portion of the insulating layer exposed by the plurality of trimmed apertures to provide a plurality of trenches and providing a plurality of lines in the plurality of trenches. In a second aspect, the method and system include providing a reverse mask on the insulating layer and removing a first portion of the insulating layer exposed by the plurality of apertures to provide a plurality of trenches.

Abstract: A semiconductor apparatus and fabrication method for forming oxide isolation regions in a semiconductor substrate for use in forming self-aligned, floating gate MOS structures or other semiconductor devices. The method includes providing a semiconductor substrate member prefabricated having a barrier oxide layer, a polysilicon layer and a plurality of spaced apart silicon nitride layer portions fabricated on the polysilicon layer. The nitride layer portions delineate regions for forming the self-aligned floating gate MOS structures, as well as delineating portions of the silicon dioxide layer and portions of said polysilicon layer that are unprotected by the plurality of silicon nitride layer portions. The method further includes the step of implanting oxygen O2 ions into regions of the substrate, including those unprotected portions of the silicon dioxide layer and portions of the polysilicon layer to form the oxide isolation regions.

Abstract: A method and system for providing a plurality of lines in a core of a memory device from a layer of material is disclosed. The method and system include utilizing a mask to print a physical mask for the plurality of lines. The mask includes a plurality of polygons for each of the plurality of lines. The plurality of polygons are for printing a pattern for the physical mask, the pattern of the physical mask covering a first portion the layer of material. In one aspect, the plurality of polygons includes a first polygon having at least one end and at least one hammerhead structure at the at least one end. In another aspect, the plurality of polygons includes a first polygon having at least one end and at least one serit structure at the at least one end. The method and system also include removing a second portion of the layer of material exposed by the pattern of the physical mask to form the plurality of lines. Thus, the plurality of lines has reduced foreshortening and reduced end-rounding.

Abstract: A method and system for providing a plurality of lines in a semiconductor memory device is disclosed. The method and system include providing a semiconductor substrate, providing a plurality of lines and providing an adjacent feature. The plurality of lines includes an adjacent line adjacent to the adjacent feature. The each of the plurality of lines has a line width that is substantially the same for each of the plurality of lines. The plurality of lines is preferably formed utilizing a mask to print a physical mask for the plurality of lines and the adjacent feature. The mask includes a mask assist feature between at least a first polygon for the adjacent line and at least a second polygon for the adjacent feature. The mask assist feature has a size that is sufficiently large to affect the width of the adjacent line and that is sufficiently small to prevent a corresponding feature from being printed on the physical mask.

Abstract: In one embodiment, the present invention relates to a method of forming a conductive structure having a width of about 100 nm or less, involving the steps of providing a substrate having a conductive film; patterning a sidewall template over a first portion of the conductive film wherein a second portion of the conductive film is exposed, the sidewall template having at least one sidewall over the conductive film; depositing a sidewall film over the conductive film and the sidewall template, the sidewall film having a vertical portion adjacent the sidewall of the sidewall template and a horizontal portion in areas not adjacent the sidewall of the sidewall template; removing the horizontal portion of the sidewall film exposing a third portion of the conductive film; removing the sidewall template exposing a fourth portion of the conductive film; and etching the third portion and the fourth portion of the conductive film thereby providing the conductive structure having a width of about 100 nm or less underlyin

Abstract: In one embodiment, the present invention relates to a method of treating a resist layer involving the steps of providing the resist layer having a first thickness, the resist layer comprising a polymer having a labile group; contacting a coating containing at least one cleaving compound with the resist layer to form a deprotected resist layer at an interface between the resist layer and the coating; and removing the coating and the deprotected resist layer leaving a resist having a second thickness, wherein the second thickness is smaller than the first thickness.

Abstract: A system and method is provided that facilitates the application of a uniform layer of developer material on a photoresist material layer. The system includes a multiple tip nozzle and a movement system that moves the nozzle to an operating position above a central region of a photoresist material layer located on a substrate, and applies a volume of developer as the nozzle scan moves across a predetermined path. The movement system moves the nozzle in two dimensions by providing an arm that has a first arm member that is pivotable about a first rotational axis and a second arm member that is pivotable about a second rotational axis or is movable along a translational axis. The system also provides a measurement system that measures the thickness uniformity of the developed photoresist material layer disposed on a test wafer. The thickness uniformity data is used to reconfigure the predetermined path of the nozzle as the developer is applied.

Abstract: The present invention relates to wafer alignment. A reticle is employed which includes, a design and first and second alignment marks. The second alignment mark is symmetric to the first alignment mark such that a reticle center point is a midpoint of the first and second alignment marks. The first alignment mark is printed on a surface layer of the wafer. The second alignment mark is printed on the surface layer at an offset from the first alignment mark. A virtual alignment mark is determined, the virtual alignment mark being a midpoint of the printed first and second alignment marks. The virtual alignment mark is employed to facilitate aligning the wafer. The symmetric relationship between the first and second alignment mark results in the negation of print errors of the marks due to reticle rotation and/or lens magnification with respect to the virtual alignment mark. The employment of the virtual alignment mark in wafer alignment substantially facilitates mitigation of overlay error.

Abstract: A system and method is provided that facilitates the application of a uniform layer of developer material on a photoresist material layer. The system includes a nozzle adapted to apply a predetermined volume of developer material on a photoresist material layer along a linear path having a length approximately equal to the diameter of the photoresist material layer. A movement system moves the nozzle to a first position offset from a central region of the photoresist material layer for applying a first predetermined volume of developer material to the photoresist material layer while the developer material is spin coated. The movement system also moves the nozzle to a second position offset from the central region for applying a second predetermined volume of developer material to the photoresist material layer while the developer is spin coated. The first position is located on an opposite side of the central region with respect to the second position.

Abstract: A method for creating a roughened surface on a material exposed to light during a photolithographic process is provided. The roughened surface is created on a surface of the material via a plasma etch process. The roughened surface diffuses light incident to the material such that the diffused light causes insubstantial damage to a photoresist subsequently formed on the material.

Abstract: A system for monitoring and regulating a photoresist temperature in a maskless lithography pattern transfer process is disclosed. The system includes a photoresist layer overlying a substrate and a material associated with the photoresist layer, wherein the material exhibits a transformation over variations in temperature. The system also includes a detection system for detecting the transformation in the material and a processor operatively coupled to the detection system. The processor receives information associated with the detected transformation and uses the information to control a tool being used for the pattern transfer, thereby reducing variations in temperature in the resist during pattern transfer. In addition, a method of monitoring and regulating a photoresist temperature in a maskless lithography pattern transfer process is disclosed.

Abstract: In one embodiment, the present invention relates to a method of forming a conductive structure having a width of about 100 nm or less, involving the steps of providing a substrate having a conductive film; patterning a mask over a first portion of the conductive film wherein a second portion of the conductive film is exposed; partially etching the second portion of the conductive film thereby forming a sidewall in the conductive film; removing the mask; depositing a sidewall film over the conductive film, the sidewall film having a vertical portion adjacent the sidewall of the conductive film and a horizontal portion in areas not adjacent the sidewall of the conductive film; removing the horizontal portion of the sidewall film exposing a third portion of the conductive film; and etching the third portion of the conductive film thereby providing the conductive structure having a width of about 100 nm or less underlying the vertical portion of the sidewall film.

Abstract: A system for regulating temperature of a developer is provided. The system includes a plurality of optical fibers, each optical fiber directing radiation to respective portions of the developer. Radiation reflected from the respective portions are collected by a measuring system which processes the collected radiation. The reflected radiation are indicative of the temperature of the respective portions of the developer. The measuring system provides developer temperature related data to a processor which determines the temperature of the respective portions of the developer. The system also includes a plurality of heating devices; each heating device corresponds to a respective portion of the developer and provides for the heating thereof. The processor selectively controls the heating devices so as to regulate temperature of the respective portions of the developer.

Abstract: A method of repairing defects in a photomask used in the formation of a semiconductor wafer includes the use of a scanning tunneling microscope. The scanning tunneling microscope includes a very sharp tip having a diameter on the order of 100 Å or less. In order to remove excess material from a mask layer in the photomask, the tip is placed into contact with those regions having such excess material and the tip is used to scrape the excess material away. In order to add material to voids in a mask layer of the photomask, the tip is placed in proximity to those areas in need of the excess material and caused to deposit such material upon, for example, application of a bias voltage to the tip.

Abstract: The present invention relates to a method for fabricating interconnecting lines and vias in a layer of insulating material. A via is formed in the layer of insulating material. A protective material is formed so as to be conformal to at least edges and sidewalls of the via, the protective material facilitating shielding of at least the edges and sidewalls of the via from a trench etch step. The trench etch step is performed to form a trench opening in the insulating material. The via and trench are filled with a conductive metal.

Abstract: In one embodiment, the present invention relates to a method of making a sub-lithographic structure involving the steps of providing a nitrogen rich film over a portion of a substrate; depositing a photoresist over the nitrogen rich film and the substrate, wherein the photoresist and the nitrogen rich film interact and form a thin desensitized resist layer around an interface between the photoresist and the nitrogen rich film; exposing the photoresist to radiation; developing the photoresist exposing the thin desensitized resist layer; directionally etching a portion of the thin desensitized resist layer; and removing the nitrogen rich film leaving the sub-lithographic structure on the substrate.

Abstract: A method for fabricating a first memory cell and a second memory cell electrically isolated from each other is provided. A first polysilicon (poly I) layer is formed on an oxide coated substrate. Then, a sacrificial oxide layer and nitride layer are formed for masking the poly I layer. At least a portion of the masking layer is etched to pattern the first memory cell and the second memory cell and an unmasked portion therebetween. The unmasked portion of the poly I layer is transformed into an insulator via thermal oxidation such that the insulator separates a floating gate of the first memory cell from a floating gate of the second memory cell. The insulator is etched so as to form a gap having gradually sloping sidewalls between a floating gate of the first memory cell and a floating gate of the second memory cell, the gap isolating the floating gate of the first memory cell from the floating gate of the second memory cell.

Abstract: Self-aligned silicide contacts having a height that is at least about equal to the gate height are formed by depositing silicon over active regions of the substrate, depositing a refractory metal over the silicon, and heating the silicon and the refractory metal. The deposited silicon may be amorphous silicon in which case the deposition temperature can be as low as 580.degree. C. If polysilicon is deposited, the deposition temperature has to be at least 620.degree. C.