Abstract: The present invention provides a method for manufacturing a gate dielectric (710) that includes providing a nitrided dielectric layer (220) over a substrate (120). The nitrided dielectric layer (220) has a nonuniform concentration of nitrogen in a bulk thereof. The nitrided dielectric layer (220) is exposed to oxygen radicals (410), resulting in a reduction of the non-uniformity.

Abstract: The present invention provides a method for manufacturing a gate dielectric (710) that includes providing a nitrided dielectric layer (220) over a substrate (120). The nitrided dielectric layer (220) has a nonuniform concentration of nitrogen in a bulk thereof. The nitrided dielectric layer (220) is exposed to oxygen radicals (410), resulting in a reduction of the non-uniformity.

Abstract: The present invention, in one aspect, provides a method of manufacturing a microelectronics device 100 that includes depositing a first gate dielectric layer 160 over a substrate 115, subjecting the first gate dielectric layer 160 to a first nitridation process, forming a second gate dielectric layer 165 over the substrate 115 and having a thickness less than a thickness of the first gate dielectric layer 160, and subjecting the first and second gate dielectric layers 160, 165 to a second nitridation process, wherein the first and second nitridation processes are different. The present invention also provides a microelectronics device 100 fabricated in accordance with the method.

Abstract: The present invention, in one aspect, provides a method of manufacturing a microelectronics device 100 that includes depositing a first gate dielectric layer 160 over a substrate 115, subjecting the first gate dielectric layer 160 to a first nitridation process, forming a second gate dielectric layer 165 over the substrate 115 and having a thickness less than a thickness of the first gate dielectric layer 160, and subjecting the first and second gate dielectric layers 160,165 to a second nitridation process, wherein the first and second nitridation processes are different. The present invention also provides a microelectronics device 100 fabricated in accordance with the method.

Abstract: The present invention provides a method for manufacturing a gate dielectric, a method for manufacturing a semiconductor device, and a method for manufacturing an integrated circuit. The method for manufacturing the gate dielectric, without limitation, may include forming a nitrided dielectric layer (520) over a substrate (310), the nitrided dielectric layer (520) having a non-uniformity of nitrogen in a bulk thereof, and removing at least a portion of the nitrided dielectric layer (520) using a high temperature chemical treatment, the removing reducing the non-uniformity.

Abstract: A method of providing critical dimension (CD) gate control during photolithography is achieved by scanning a trial wafer from a batch by an exposure tool and then measuring the gate width to determine shot zones for bi-shot (BSE) exposure. The time delay based on shot or exposure order is determined for each BSE zone. The shot or exposure dose for the other wafers from the same or similar batch is then determined on the bi-shot exposure and the shot order.

Abstract: A lithographic method of forming submicron polysilicon features on a semiconductor substrate, including the steps of coating said substrate with an anti-reflective coating (ARC) comprising two layers having matched indices of refraction (n) and extinction coefficient (k) selected to reduce reflection to less than 1% with 193 nm wavelength exposure. The ARC is subsequently patterned to serve as an etch hardmask. Preferably the ARC mask consists of a first layer of between 300 and 1500 angstroms of silicon rich silicon nitride having an extinction coefficient of from 0.77 to 1.07, and a second layer of between 170 and 320 angstroms of silicon oxynitride having an extinction coefficient of about 0.32.

Abstract: A lithographic method of forming submicron polysilicon features on a semiconductor substrate, including the steps of coating said substrate with an anti-reflective coating (ARC) comprising two layers having matched indices of refraction (n) and extinction coefficient (k) selected to reduce reflection to less than 1% with 193 nm wavelength exposure. The ARC is subsequently patterned to serve as an etch hardmask. Preferably the ARC mask consists of a first layer of between 300 and 1500 angstroms of silicon rich silicon nitride having an extinction coefficient of from 0.77 to 1.07, and a second layer of between 170 and 320 angstroms of silicon oxynitride having an extinction coefficient of about 0.32.

Abstract: A method of providing critical dimension (CD) gate control during photolithography is achieved by scanning a trial wafer from a batch by an exposure tool and then measuring the gate width to determine shot zones for bi-shot (BSE) exposure. The time delay based on shot or exposure order is determined for each BSE zone. The shot or exposure dose for the other wafers from the same or similar batch is then determined on the bi-shot exposure and the shot order.

Abstract: A lithographic method of forming submicron polysilicon features on a semiconductor substrate, including the steps of coating said substrate with an anti-reflective coating (ARC) comprising two layers having matched indices of refraction (n) and extinction coefficient (k) selected to reduce reflection to less than 1% with 193 nm wavelength exposure. The ARC is subsequently patterned to serve as an etch hardmask. Preferably the ARC mask consists of a first layer of between 300 and 1500 angstroms of silicon rich silicon nitride having an extinction coefficient of from 0.77 to 1.07, and a second layer of between 170 and 320 angstroms of silicon oxynitride having an extinction coefficient of about 0.32.

Abstract: A lithographic method of forming submicron polysilicon features on a semiconductor substrate, including the steps of coating said substrate with an anti-reflective coating (ARC) comprising two layers having matched indices of refraction (n) and extinction coefficient (k) selected to reduce reflection to less than 1% with 193 nm wavelength exposure. The ARC is subsequently patterned to serve as an etch hardmask. Preferably the ARC mask consists of a first layer of between 300 and 1500 angstroms of silicon rich silicon nitride having an extinction coefficient of from 0.77 to 1.07, and a second layer of between 170 and 320 angstroms of silicon oxynitride having an extinction coefficient of about 0.32.

Abstract: A method is described for forming a patterned polysilicon, amorphous, or single crystal silicon layer. The method comprises forming a consumable mask (50, 60) that is simultaneously removed while etching the underlying film (30).

Abstract: A method of forming a floating gate memory array is provided that uses a two step etch process to prevent the formation of unwanted trenches 66 into the semiconductor substrate 26. The process may be accomplished by a first etch which is substantially not selective between silicon and dielectric materials. A second etch process is then used which is highly selective to dielectric materials.