Patent application number | Description | Published |
20100183961 | INTEGRATED CIRCUIT LAYOUT DESIGN - Provided is a method including layout design of an integrated circuit. A first pattern is provided. The first pattern includes an array of dummy line features and a plurality of spacer elements abutting the dummy line features. A second pattern is provided. The second pattern defines an active region of an integrated circuit device. An edge spacer element of the active region is determined. A dummy line feature of the array of dummy line features is biased (e.g., increased in width), the dummy line feature is adjacent an edge spacer element. | 07-22-2010 |
20100201961 | System For Improving Critical Dimension Uniformity - A system for improving substrate critical dimension uniformity is described. The system includes an exposing means for exposing a plurality of mask patterns on a first plurality of substrates at predetermined locations with common splits of focus ({F | 08-12-2010 |
20100203734 | METHOD OF PITCH HALVING - The present disclosure provides a method of fabricating a semiconductor device that includes forming a mask layer over a substrate, forming a dummy layer having a first dummy feature and a second dummy feature over the mask layer, forming first and second spacer roofs to cover a top portion of the first and second dummy features, respectively, and forming first and second spacer sleeves to encircle side portions of the first and second dummy features, respectively, removing the first spacer roof and the first dummy feature while protecting the second dummy feature, removing a first end portion and a second end portion of the first spacer sleeve to form spacer fins, and patterning the mask layer using the spacer fins as a first mask element and the second dummy feature as a second mask element. | 08-12-2010 |
20110151359 | INTEGRATED CIRCUIT LAYOUT DESIGN - Provided is a photolithography apparatus including a photomask. The photomask includes a pattern having a plurality, of features, in an example, dummy line features. The pattern includes a first region being in the form of a localized on-grid array and a second region where at least one of the features has an increased width. The apparatus may include a second photomask which may define an active region. The feature with an increased width may be adjacent, and outside, the defined active region. | 06-23-2011 |
20120021589 | METHOD OF FABRICATION OF A SEMICONDUCTOR DEVICE HAVING REDUCED PITCH - Provided is a photolithography apparatus including a photomask. The photomask includes a pattern having a plurality of features, in an example, dummy line features. The pattern includes a first region being in the form of a localized on-grid array and a second region where at least one of the features has an increased width. The apparatus may include a second photomask which may define an active region. The feature with an increased width may be adjacent, and outside, the defined active region. | 01-26-2012 |
20120244460 | MECHANISMS FOR PATTERNING FINE FEATURES - The embodiments described provide mechanisms for patterning features for advanced technology nodes with extreme ultraviolet lithography (EUVL) tools. One or more EUV pre-masks are generated by using a mask writer to form an EUV mask with an EUV scanner. The wafers are then patterned by using the EUV mask. The demagnification factor of the EUV scanner(s) used in preparing the EUV mask by exposing the EUV pre-mask(s) enable the wafers prepared by such mechanisms to meet the requirements for the advanced technology nodes. | 09-27-2012 |
20130260288 | EXTREME ULTRAVIOLET LITHOGRAPHY PROCESS AND MASK - A process of an extreme ultraviolet lithography (EUVL) is disclosed. The process includes receiving an extreme ultraviolet (EUV) mask with multiple states. Different states of the EUV mask are assigned to adjacent polygons and a field. The EUV mask is exposed by a nearly on-axis illumination (ONI) with partial coherence σ less than 0.3 to produce diffracted lights and non-diffracted lights. Most of the non-diffracted lights are removed. The diffracted lights and the not removed non-diffracted lights are collected and directed to expose a target by a projection optics box. | 10-03-2013 |
20130280643 | REFLECTIVE MASK AND METHOD OF MAKING SAME - A reflective mask is described. The mask includes a low thermal expansion material (LTEM) substrate, a conductive layer deposited on a first surface of the LTEM substrate, a stack of reflective multilayers (ML) deposited on a second surface of the LTEM substrate, a capping layer deposited on the stack of reflective ML, a first absorption layer deposited on the first capping layer, a main pattern, and a border ditch. The border ditch reaches to the capping layer, the second absorption layer deposited inside the border ditch, and the second absorption layer contacts the capping layer. | 10-24-2013 |
20140038086 | Phase Shift Mask for Extreme Ultraviolet Lithography and Method of Fabricating Same - A mask and method of fabricating same are disclosed. In an example, a mask includes a substrate, a reflective multilayer coating disposed over the substrate, an Ag | 02-06-2014 |
20140038090 | Extreme Ultraviolet Lithography Mask and Multilayer Deposition Method for Fabricating Same - A mask, method of fabricating same, and method of using same are disclosed. In an example, a mask includes a substrate and a reflective multilayer coating deposited over the substrate. The reflective multilayer coating is formed by positioning the substrate such that an angle α is formed between a normal line of the substrate and particles landing on the substrate and rotating the substrate about an axis that is parallel with a landing direction of the particles. In an example, reflective multilayer coating includes a first layer and a second layer deposited over the first layer. A phase defect region of the reflective multilayer coating includes a first deformation in the first layer at a first location, and a second deformation in the second layer at a second location, the second location laterally displaced from the first location. | 02-06-2014 |
20140065521 | METHOD FOR MASK FABRICATION AND REPAIR - A method for repairing phase defects for an extreme ultraviolet (EUV) mask is disclosed. The method includes receiving a patterned EUV mask with at least one phase-defect region, determining location and size of the phase-defect region, depositing an absorber material to cover the phase-defect region and removing a portion of the patterned absorption layer near the phase-defect region in the patterned EUV mask to form an absorber-absent region. | 03-06-2014 |
20140113222 | Mask for Use in Lithography - A mask, or photomask, is used in lithography systems and processes. The mask includes a first polygon of a first state and a second polygon of a second state. The mask also includes a field of the first state and a third polygon of the second state, and in the field. The first and second states are different, and the first and second polygons are located outside of the field. | 04-24-2014 |
20140218713 | Extreme Ultraviolet Lithography Process - 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. | 08-07-2014 |
20140253892 | Extreme Ultraviolet Lithography Projection Optics System and Associated Methods - The present disclosure provides an extreme ultraviolet lithography system. The extreme ultraviolet lithography system includes a projection optics system to image a pattern of a mask on a wafer. The projection optics system includes between two to five mirrors. The two to five mirrors are designed and configured to have a numerical aperture less than about 0.50, an image field size at the wafer hat is greater than or equal to about 20 mm, and a pupil plane that includes central obscuration. In an example, the central obscuration has a radius that is less than or equal to 50% of a radius of the pupil plane. In an example, the central obscuration has an area that is less than or equal to 25% of an area of the pupil plane. | 09-11-2014 |
20140268086 | Extreme Ultraviolet Lithography Process and Mask - The present disclosure is directed towards lithography processes. In one embodiment, a patterned mask is provided. An information of a position of diffraction light (PDL) on a pupil plane of a projection optics box (POB) is used to define as a light-transmitting region of a pupil filter. The patterned mask is exposed by an on-axis illumination (ONI) with partial coherence σ less than 0.3. The pupil filter is used to transmit diffraction light to a target. | 09-18-2014 |
20140268087 | Lithography and Mask for Resolution Enhancement - A lithography process in a lithography system includes loading a mask having multiple mask states and having a mask pattern consisting of a plurality of polygons and a field. Different mask states are assigned to adjacent polygons and the field. The lithography process further includes configuring an illuminator to generate an illumination pattern on an illumination pupil plane of the lithography system; configuring a pupil filter on a projection pupil plane of the lithography system with a filtering pattern determined according to the illumination pattern; and performing an exposure process to a target with the illuminator, the mask, and the pupil filter. The exposure process produces diffracted light and non-diffracted light behind the mask and the pupil filter removes most of the non-diffracted light. | 09-18-2014 |
20140268091 | Extreme Ultraviolet Lithography Process and Mask - A system and process of an extreme ultraviolet lithography (EUVL) is disclosed. The system and process includes receiving a mask with two states, which have 180 degree phase difference to each other. These different states are assigned to adjacent main polygons and adjacent assist polygons of the mask. A nearly on-axis illumination (ONI) with partial coherence σ less than 0.3 is utilized to expose the mask to produce diffracted lights and non-diffracted lights. A majority portion of the non-diffracted lights and diffracted light with diffraction order higher than 1 are removed. Diffracted light having +1-st and −1-st diffracted order are collected and directed by a projection optics box (POB) to expose a target. | 09-18-2014 |
20140268092 | Extreme Ultraviolet Lithography Process and Mask - A process of an extreme ultraviolet lithography (EUVL) is disclosed. The process includes receiving an extreme ultraviolet (EUV) mask with multiple states. These different states of the EUV mask are assigned to adjacent polygons and adjacent assist polygons. The EUV mask is exposed by a nearly on-axis illumination (ONI) with partial coherence σ less than 0.3 to produce diffracted lights and non-diffracted lights. Most of the non-diffracted lights reflected from main polygons and reflected lights from assist polygons are removed. The diffracted lights and the not removed non-diffracted lights reflected from main polygons are collected and directed to expose a target by a projection optics box. | 09-18-2014 |
20140272678 | Structure and Method for Reflective-Type Mask - The present disclosure provides an embodiment of a reflective mask that includes a substrate; a reflective multilayer formed on the substrate; a capping layer formed on the reflective multilayer and having a hardness greater than about 8; and an absorber layer formed on the capping layer and patterned according to an integrated circuit layout. | 09-18-2014 |
20140272679 | Extreme Ultraviolet Lithography Process and Mask - An extreme ultraviolet lithography (EUVL) process is disclosed. The process comprises receiving a mask. The mask includes a low thermal expansion material (LTEM) substrate, a reflective multilayer (ML) over one surface of the LTEM substrate, a first region having a phase-shifting layer over the reflective ML, and a second region having no phase-shifting layer over the reflective ML. The EUVL process also comprises exposing the mask by a nearly on-axis illumination with partial coherence less than 0.3 to produce diffracted light and non-diffracted light, removing at least a portion 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. | 09-18-2014 |
20140272680 | Method For Mask Fabrication And Repair - A method for repairing a phase-defect region in a patterned mask for extreme ultraviolet lithography (EUVL) is disclosed. A patterned mask for EUVL is received. The patterned mask includes an absorptive region having an absorption layer over a defect-repairing-enhancement (DRE) layer, a reflective region having the DRE layer without the absorption layer on top of it, a defect and a phase-defect region resulting from the defect and intruding the reflective region. A location and a shape of the phase-defect region is determined. A portion or portions of the DRE layer in the reflective region is removed according to the location and the shape of the phase-defect region to compensate the effect of the phase-defect region. | 09-18-2014 |
20140272682 | Extreme Ultraviolet Lithography Process and Mask - The present disclosure is directed towards an extreme ultraviolet (EUV) mask. The EUV mask includes a low thermal expansion material (LTEM) substrate. The EUV mask has a first region and a second region. The EUV mask also includes a structure disposed in the first region. The structure has a multiple facets with an angle to each other. The EUV mask also includes a conformal reflective multilayer (ML) disposed over the structure in the first region and over the LTEM substrate in the second region. The conformal reflective ML has a similar surface profile as the structure in the first region and a flat surface profile in the second region. | 09-18-2014 |
20140272683 | Method Of Fabricating Mask - A method for fabricating an extreme ultraviolet (EUV) mask includes providing a low thermal expansion material (LTEM) layer. A reflective multiple-layer (ML) is deposited over the LTEM layer. A flowable-photosensitive-absorption-layer (FPhAL) is spin coated over the reflective ML. The FPhAL is patterned by a lithography process to form a patterned absorption layer. | 09-18-2014 |
20140272686 | Mask for Extreme Ultraviolet Lithography and Method of Fabricating Same - A mask and method of fabricating same are disclosed. In an example, a mask includes a substrate, a reflective multilayer coating disposed over the substrate and a patterned absorption layer disposed over the reflective multilayer. The patterned absorption layer has a mask image region and a mask border region. The exemplary mask also includes a mask border frame disposed over the mask border region. The mask border frame has a top surface and a bottom surface. The top surface is not parallel to the bottom surface. | 09-18-2014 |
20140272718 | Lithography Process - 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. | 09-18-2014 |
20140272720 | Multiple Exposures in Extreme Ultraviolet Lithography - An extreme ultraviolet lithography method is disclosed. In an example, the EUVL method comprises providing at least two mask areas having a same pattern, forming a resist layer over a substrate, determining an optimized exposure dose based on an exposure dose for a pre-specified pattern on one of the at least two mask areas to achieve a pre-specified target dimension under a corresponding single exposure process, and performing a multiple exposure process for exposing a same area of the resist layer to the same pattern. The multiple exposure process comprises a plurality of exposure processes, wherein each of the plurality of exposure processes uses an exposure dose that is less than the optimized exposure dose and a sum of the exposure dose of each of the plurality of exposure processes is approximately equal to the optimized exposure dose. | 09-18-2014 |
20140272721 | Extreme Ultraviolet Lithography Process and Mask - An extreme ultraviolet lithography (EUVL) process is performed on a target, such as a semiconductor wafer, having a photosensitive layer. The method includes providing a one-dimensional patterned mask along a first direction. The patterned mask includes a substrate including a first region and a second region, a multilayer mirror above the first and second regions, an absorption layer above the multilayer mirror in the second region, and a defect in the first region. The method further includes exposing the patterned mask by an illuminator and setting the patterned mask and the target in relative motion along the first direction while exposing the patterned mask. As a result, an accumulated exposure dose received by the target is an optimized exposure dose. | 09-18-2014 |
20140285789 | Lithography Method and Structure for Resolution Enhancement with a Two-State Mask - A lithography process in a lithography system includes loading a mask that includes two mask states defining an integrated circuit (IC) pattern. The IC pattern includes a plurality of main polygons, wherein adjacent main polygons are assigned to different mask states; and a background includes a field in one of the mask states and a plurality of sub-resolution polygons in another of the two mask states. The lithography process further includes configuring an illuminator to generate an illuminating pattern on an illumination pupil plane of the lithography system; configuring a pupil filter on a projection pupil plane of the lithography system with a filtering pattern determined according to the illumination pattern; and performing an exposure process to a target with the illuminator, the mask, and the pupil filter. The exposure process produces diffracted light and non-diffracted light behind the mask and the pupil filter removes most of the non-diffracted light. | 09-25-2014 |
20140342272 | Method to Define Multiple Layer Patterns With a Single Exposure by E-Beam Lithography - The present disclosure provides a method that includes forming a first resist layer on a substrate; forming a second resist layer over the first resist layer; and performing an electron-beam (e-beam) lithography exposure process to the first resist layer and the second resist layer, thereby forming a first latent feature in the first resist layer and a second latent feature in the second resist layer. | 11-20-2014 |
20140342564 | Photomask With Three States For Forming Multiple Layer Patterns With A Single Exposure - The present disclosure provides one embodiment of a mask for a lithography exposure process. The mask includes a mask substrate; a first mask material layer patterned to have a first plurality of openings that define a first layer pattern; and a second mask material layer patterned to have a second plurality of openings that define a second layer pattern. | 11-20-2014 |
20140377693 | Extreme Ultraviolet Lithography Mask and Multilayer Deposition Method for Fabricating Same - A mask, method of fabricating same, and method of using same are disclosed. In an example, a mask includes a substrate and a reflective multilayer coating deposited over the substrate. The reflective multilayer coating is formed by positioning the substrate such that an angle α is formed between a normal line of the substrate and particles landing on the substrate and rotating the substrate about an axis that is parallel with a landing direction of the particles. In an example, reflective multilayer coating includes a first layer and a second layer deposited over the first layer. A phase defect region of the reflective multilayer coating includes a first deformation in the first layer at a first location, and a second deformation in the second layer at a second location, the second location laterally displaced from the first location. | 12-25-2014 |
20150037712 | Extreme Ultraviolet (EUV) Mask, Method Of Fabricating The EUV Mask And Method Of Inspecting The EUV Mask - An out-of-band (OoB) suppression layer is applied on a reflective multiplayer (ML) coating, so as to avoid the OoB reflection and to enhance the optical contrast at 13.5 nm A material having a low reflectivity at wavelength of 193-257 nm, for example, silicon carbide (SiC), is used as the OoB suppression layer. A method of fabricating an EUV mask having the OoB suppression layer and a method of inspecting an EUV mask having the OoB suppression are also provided. | 02-05-2015 |
20150064611 | Extreme Ultraviolet (Euv) Mask And Method Of Fabricating The Euv Mask - A Cu-containing material is provided as an absorber layer of an EUV mask. With the absorber layer of the Cu-containing material, the same lithography performance of a conventional absorber in 70 nm thickness of TaBN can be achieved by only a 30-nm thickness of the absorber layer according to the various embodiments of the present disclosure. Furthermore, the out-off-band (OOB) flare of the radiation light in 193-257 nm can be reduced so as to achieve the better lithography performance. | 03-05-2015 |
20150072271 | Extreme Ultraviolet Lithography Process and Mask - A system and process of an extreme ultraviolet lithography (EUVL) is disclosed. An EUVL process includes receiving a mask pair having a same pattern. The mask pair includes an extreme ultraviolet (EUV) mask and a low EUV reflectivity mask. A first exposure process is performed by using the EUV mask to expose a substrate. A second exposure process is performed by using the low EUV reflectivity mask to expose the same substrate. The first exposure process is conducted according to a first exposure dose matrix and the second exposure process is conducted according to a second exposure dose matrix. | 03-12-2015 |