Abstract: The present disclosure provides a method in accordance with some embodiments. A wafer is grinded from a back side. The wafer is inserted into an opening defined by a frame holder. The frame holder is attached to a carrier through a temporary layer. A front side of the wafer is attached to the temporary layer. Thereafter, the wafer is etched from the back side until the wafer reaches a predetermined thickness. Thereafter, the frame holder and the wafer therein are separated from the temporary layer and the carrier.

Abstract: Various methods are disclosed herein for reducing (or eliminating) printability of mask defects during lithography processes. An exemplary method includes performing a first lithography exposing process and a second lithography exposing process using a mask to respectively image a first set of polygons oriented substantially along a first direction and a second set of polygons oriented substantially along a second direction on a target. During the first lithography exposing process, a phase distribution of light diffracted from the mask is dynamically modulated to defocus any mask defect oriented at least partially along both the first direction and a third direction that is different than the first direction. During the second lithography exposing process, the phase distribution of light diffracted from the mask is dynamically modulated to defocus any mask defect oriented at least partially along both the second direction and a fourth direction that is different than the third direction.

Abstract: The present disclosure provides a method in accordance with some embodiments. A wafer is grinded from a back side. The wafer is inserted into an opening defined by a frame holder. The frame holder is attached to a carrier through a temporary layer. A front side of the wafer is attached to the temporary layer. Thereafter, the wafer is etched from the back side until the wafer reaches a predetermined thickness. Thereafter, the frame holder and the wafer therein are separated from the temporary layer and the carrier.

Abstract: A mask for extreme ultraviolet lithography (EUVL) is disclosed. The mask includes a low thermal expansion material (LTEM) layer; and a reflective multilayer (ML) above one surface of the LTEM layer, wherein the reflective ML has a first thickness in a first reflective region and a second thickness in a second reflective region, wherein the second thickness is different from the first thickness.

Abstract: A lithography system includes a radiation source configured to generate an extreme ultraviolet (EUV) light. The lithography system includes a mask that defines one or more features of an integrated circuit (IC). The lithography system includes an illuminator configured to direct the EUV light onto the mask. The mask diffracts the EUV light into a 0-th order ray and a plurality of higher order rays. The lithography system includes a wafer stage configured to secure a wafer that is to be patterned according to the one or more features defined by the mask. The lithography system includes a pupil phase modulator positioned in a pupil plane that is located between the mask and the wafer stage. The pupil phase modulator is configured to change a phase of the 0-th order ray.

Abstract: An extreme ultraviolet lithography (EUVL) system is disclosed. The system includes an extreme ultraviolet (EUV) mask with three states having respective reflection coefficient is r1, r2 and r3, wherein r3 is a pre-specified value that is a function of r1 and r2. The system also includes a nearly on-axis illumination (ONI) with partial coherence ? less than 0.3 to expose the EUV mask to produce diffracted light and non-diffracted light. The system further includes a projection optics box (PUB) to remove a portion of the non-diffracted light and to collect and direct the diffracted light and the remaining non-diffracted light to expose a target.

Abstract: The present disclosure provides a method in accordance with some embodiments. The method includes loading a mask to a lithography system, wherein the mask includes an one-dimensional integrated circuit (1D IC) pattern; utilizing a pupil phase modulator in the lithography system to modulate phase of light diffracted from the mask; and performing a lithography exposing process to a target in the lithography system with the mask and the pupil phase modulator.

Abstract: A pattern of features of an integrated circuit is provided. A configuration of a pupil of an extreme ultraviolet wavelength radiation beam (also referred to as an illumination mode), is selected. The selected configuration is an asymmetric, single pole configuration. At least one disparity is determined between a simulated imaging using the selected configuration and a designed imaging for the pattern of features. A parameter (also referred to as a compensation parameter) is then modified to address the at least one disparity, wherein the parameter at least one a design feature, a mask feature, and a lithography process parameter. A substrate is then exposed to the pattern of features using the selected configuration and the modified parameter.

Abstract: A method for being used in a lithography process is provided. The method includes receiving a first mask, a second mask and a substrate with a set of baseline registration marks. A first set of registration marks is formed on the substrate using the first mask and a first exposure tool, and a first set of overlay errors is determined. The first set of registration marks is removed and a second set of registration marks is formed on the substrate using the second mask and a second exposure tool. A second set of overlay errors is determined. A set of tool-induced overlay errors is generated from the first and second sets of overlay errors and used in fabricating a third mask. The third mask can then be used in the lithography process to accommodate the overlay errors caused by different exposure tools, different masks, and different mask writers.

Abstract: The present disclosure provides an extreme ultraviolet (EUV) lithography system. The EUV lithography system includes a collector having a coating surface designed to collect and reflect EUV radiation; a gas supply module; and a gas pipeline integrated with the collector and connected to the gas supply module. The gas pipeline includes inward and outward entrances into the collector. The inward and outward entrances are configured and operable to form a gas curtain on the coating surface of the collector.

Abstract: A method includes inspecting a mask to locate a defect region for a defect of the mask. A phase distribution of an aerial image of the defect region is acquired. A point spread function of an imaging system is determined. One or more repair regions of the mask are identified based on the phase distribution of the aerial image of the defect region and the point spread function. A repair process is performed to the one or more repair regions of the mask to form one or more repair features.

Abstract: A method includes inspecting a mask to locate a defect region for a defect of the mask. A phase distribution of an aerial image of the defect region is acquired. A point spread function of an imaging system is determined. One or more repair regions of the mask are identified based on the phase distribution of the aerial image of the defect region and the point spread function. A repair process is performed to the one or more repair regions of the mask to form one or more repair features.

Abstract: The present disclosure provides a photolithography mask. The photolithography mask includes a substrate that contains a low thermal expansion material (LTEM). A multilayer (ML) structure is disposed over the substrate. The ML structure is configured to reflect radiation. The ML structure contains a plurality of interleaving film pairs. Each film pair includes a first film and a second film. The first film and the second film have different material compositions. Each film pair has a respective thickness. For at least a subset of the plurality of the film pairs, the respective thicknesses of the film pairs change randomly along a predefined direction.

Abstract: An extreme ultraviolet lithography (EUVL) system for patterning a semiconductor wafer includes an extreme ultraviolet (EUV) mask. The EUV mask includes first and second states, and further includes a polygon region and an open-spacing region. The polygon region includes a plurality of main polygons separated by a plurality of first fields. The open-spacing region is located outside the polygon region, and includes a plurality of sub-resolution polygon and second fields, and does not include any main polygons. The system also includes a nearly on-axis illumination (ONI) to expose the EUV mask and optics to direct diffracted lights reflected from the EUV mask towards the semiconductor wafer.

Abstract: A method includes patterning a resist layer formed over a substrate, resulting in a resist pattern; and transferring the resist pattern to an anti-reflection coating (ARC) layer formed under the resist layer and over the substrate, resulting in a patterned ARC layer. The method further includes treating the patterned ARC layer with an ion beam, resulting in a treated patterned ARC layer, wherein the ion beam is generated with a first gas and is directed towards the patterned ARC layer at a tilt angle at least 10 degrees. The method further includes etching the substrate with the treated patterned ARC layer as an etch mask.

Abstract: Systems and methods for monitoring the focus of an EUV lithography system are disclosed. Another aspect includes a method having operations of measuring a first shift value for a first patterned set of sub-structures of a focus test structure on a wafer and measuring a second shift value for a second patterned set of sub-structures of the test structure on the wafer. The test structure may be formed on the wafer using asymmetric illumination, with the first patterned set of sub-structures having a first pitch and the second patterned set of sub-structures having a second pitch that is different from the first pitch. The method may further include determining a focus shift compensation for an illumination system based on a difference between the first shift value and the second shift value.

Abstract: The present disclosure provides a photolithography mask. The photolithography mask includes a substrate that contains a low thermal expansion material (LTEM). A multilayer (ML) structure is disposed over the substrate. The ML structure is configured to reflect radiation. The ML structure contains a plurality of interleaving film pairs. Each film pair includes a first film and a second film. The first film and the second film have different material compositions. Each film pair has a respective thickness. For at least a subset of the plurality of the film pairs, the respective thicknesses of the film pairs change randomly along a predefined direction.

Abstract: A process of an extreme ultraviolet lithography is disclosed. The process includes receiving an extreme ultraviolet (EUV) mask, an EUV radiation source and an illuminator. The process also includes exposing the EUV mask by a radiation, originating from the EUV radiation source and directed by the illuminator, with a less-than-three-degree chief ray angle of incidence at the object side (CRAO). The process further includes removing most of the non-diffracted light and collecting and directing the diffracted light and the not removed non-diffracted light by a projection optics box (POB) to expose a target.

Abstract: A method includes defining a metal pattern layer over a first dielectric layer. The first dielectric layer is disposed over an etch stop layer and the etch stop layer is disposed over a second dielectric layer. A spacer layer is grown over the metal pattern layer and the first dielectric layer. A metal trench is formed with a metal width in the first dielectric layer. A via hole is formed with a via width in the second dielectric layer.

Abstract: An apparatus comprises a low EUV reflectivity (LEUVR) mask. The LEUVR mask includes a low thermal expansion material (LTEM) layer; a reflective multilayer (ML) over the LTEM layer; and a patterned absorption layer over the reflective ML. The reflective ML has less than 2% EUV reflectivity.