摘要:
An attenuated phase shift mask comprises a first layer having a thickness to provide a transmission in the range of about 3 to 10% formed on a transparent substrate and a second layer comprising a transparent material having a thickness to provide a desired phase shift, formed on said first layer. For a phase shift of 180.degree. and i-line wavelength (365 nm), where chromium is used as the first layer, then a thickness within the range of about 25 to 75 run is employed; where silicon dioxide is used as the second layer, then a thickness of about 400 to 450 nm is employed. While the oxide may be dry-etched, an isotropic wet etch provides superior aerial images.
摘要:
An attenuated phase shift mask comprises a first layer having a thickness to provide a transmission in the range of about 3 to 10% formed on a transparent substrate and a second layer comprising a transparent material having a thickness to provide a desired phase shift, formed on said first layer. For a phase shift of 180.degree. and i-line wavelength (365 nm) where chromium is used as the first layer, then a thickness within the range of about 25 to 75 nm is employed; where silicon dioxide is used as the second layer; then a thickness of about 400 to 450 nm is employed. While the oxide may be dry-etched, an isotropic wet etch provides superior aerial images.
摘要:
A method includes providing an initial IC device design, which design has a desired set of electrical characteristics. A layout representation corresponding to the initial device design is generated. A simulation tool is used to determine whether the layout representation corresponds to an IC device design having the desired electrical characteristics. In addition, the variation between structures within IC device designed due to process variations is evaluated using the simulation tool. This variation can be used to determine whether the design is optimized.
摘要:
Prior to entering into manufacturing of a final production wafer, a series of test wafers are produced to analyze and test various structures. Each of the test wafers include a substrate, an insulating layer overlying the substrate, and a semi-conductive film layer formed over the insulating layer. The film layer is comprised of, for example, poly-silicon and has a predetermined thickness which substantially corresponds to the thickness of a film layer deposited on the final production wafer. The film layer is etched to form a desired pattern of structures and implanted with a dopant to diffuse dopant atoms thoughout. Thereafter, critical dimension measurements of the structures are taken preferably using electrical line width measurements techniques. Variations in critical dimension measurements taken from the test wafer as compared to desired predetermined line width measurements are compensated for prior to manufacturing the final production wafer so as to provide circuits with the desired electrical parameters.
摘要:
A method for fabricating a field effect transistor (FET) in and on a semiconductor substrate with local interconnects to permit the formation of minimal insulating space between polysilicon gate and the local interconnects by fabricating the source and drain of the FET and the local interconnects prior to forming the gate of the FET. A portion of an insulating layer between the source and drain is removed prior to forming the gate. Preferably, an etch stop layer on the semiconductor substrate underlying the insulating layer is used in the method.
摘要:
A method and the resulting device to permit the formation of minimal insulating space between polysilicon gates by forming an insulating layer over the polysilicon gates and protecting selected ones of the gates and the insulating layer with an etch barrier so that the opening for local interconnect metallization can be misaligned and the selected gates will be protected by its etch barrier and not be exposed to the opening. Further, local interconnect conductive material can pass over a gate or unrelated resistor without shorting the gate/resistor.
摘要:
A method of selecting a plurality of lithography process parameters for patterning a layout on a wafer includes simulating how the layout will print on the wafer for a plurality of resolution enhancement techniques (RETs), where each RET corresponds to a plurality of lithography process parameters. For each RET, the edges of structures within the simulated layout can be classified based on manufacturability. RETs that provide optimal manufacturability can be selected. In this manner, the simulation tool can be used to determine the optimal combination of scanner setup and reticle type for minimizing the variation in wafer critical dimension (CD).
摘要:
A method of producing design rules including generating a plurality of parametrically varying geometric layouts and simulating how each geometric layout will pattern on a wafer. Edges of structures within the simulated geometric layouts can be classified based on manufacturability and design rules can be created to disallow layouts demonstrating poor manufacturability.
摘要:
The invention includes an apparatus and a method of manufacturing such apparatus including the steps of: forming a layer to be patterned, forming a photosensitive layer over the layer to be patterned, patterning the photosensitive layer to form a pattern including a horizontal line and a vertical line without a space therebetween, transferring the pattern to the layer to be patterned, forming a second photosensitive layer over the pattern, patterning the second photosensitive layer to form a second pattern including a space aligned between the horizontal line and the vertical line, and transferring the second pattern to the layer to be patterned to form a third pattern including a horizontal line and a vertical line with a space therebetween, the space including a width dimension achievable at a resolution limit of lithography.
摘要:
A mask generation method can enhance clear field phase shift masks using a chrome border around phase 180 regions. An exemplary method involves identifying edges of a 180 degree phase pattern, expanding these edges, and merging the expansions with chrome. An alternative method involves oversizing and undersizing phase 180 data, taking the difference, and merging the difference with chrome. The chrome region on the phase mask can improve mask generation by allowing the chrome on the mask to fully define the quartz etch.