Abstract: A method of forming a three dimensional feature inwardly of a surface of a material includes providing a droplet dispenser including an outlet configured to dispense discrete droplets of a liquid material having a reactant therein capable of reacting with, and thereby removing, portions of the material layer with which the droplets come into contact, providing a support configured support the material thereon, the support, and the droplet dispenser, movable with respect to one another, such that the outlet of the droplet dispenser is positionable over different discrete areas of the surface of the material, and positioning the surface of the material under the droplet dispenser, and dispensing droplets to discrete portions of the surface of the material in a desired area thereof, to remove at least a portion of the material in the desired area and thereby form a three dimensional recess inwardly of the surface of the material.

Abstract: Embodiments of the present disclosure relate to methods for positioning masks in a propagation direction of a light source. The masks correspond to a pattern to be written into a photoresist layer of a substrate. The masks are positioned by stitching a first mask and a second mask. The first mask includes a set of first features having first feature extensions extending therefrom at first feature interfaces. The second mask includes a set of second features having second feature extensions extending therefrom at second feature interfaces. Each first feature extension stitches with each corresponding second feature extension to form each stitched portion of a first stitched portion of the first pair of masks. The stitched portion of the first pair of masks defines a portion of the pattern to be written into the photoresist layer.

Abstract: Embodiments of the present disclosure relate to optical device films and methods of forming optical device films. Specifically, embodiments described herein provide for an optical device film having a constant oxygen-concentration, a first concentration profile of the first material, and a second concentration profile of the second material. The first material, described and referenced to herein, has a first refractive index about 2.0 or greater and the second material has a second refractive index less than 2.0.

Abstract: Embodiments of the present disclosure generally relate to methods and materials for optical device fabrication. More specifically, embodiments described herein provide for optical film deposition methods and materials to expand the process window for amorphous optical film deposition via incorporation of dopant atoms by suppressing the crystal growth of optical materials during deposition. By enabling amorphous films to be deposited at higher temperatures, significant cost savings and increased throughput are possible.

Abstract: Methods for patterning of multi-depth layers for the fabrication of optical devices are provided. In one embodiment, a method is provided that includes disposing a resist layer over a device layer disposed over a top surface of a substrate, the device layer having a first portion and a second portion, patterning the resist layer to form a first resist layer pattern having a plurality of first openings and a second resist layer pattern having a plurality of second openings, and etching exposed portions of the device layer defined by the plurality of first openings and the plurality of second openings, wherein the plurality of first openings are configured to form at least a portion of a plurality of first structures within the optical device, and the plurality of second openings are configured to form at least a portion of a plurality of second structures within the optical device.

Abstract: A method of forming patterned features on a substrate is provided. The method includes positioning a plurality of masks arranged in a mask layout over a substrate. The substrate is positioned in a first plane and the plurality of masks are positioned in a second plane, the plurality of masks in the mask layout have edges that each extend parallel to the first plane and parallel or perpendicular to an alignment feature on the substrate, the substrate includes a plurality of areas configured to be patterned by energy directed through the masks arranged in the mask layout. The method further includes directing energy towards the plurality of areas through the plurality of masks arranged in the mask layout over the substrate to form a plurality of patterned features in each of the plurality of areas.

Abstract: Optical grating components and methods of forming are provided. In some embodiments, a method includes providing a substrate, and etching a plurality of trenches into the substrate to form an optical grating. The optical grating may include a plurality of angled trenches, wherein a depth of a first trench of the plurality of trenches varies between at least one of the following: a first lengthwise end of the first trench and a second lengthwise end of the first trench, and between a first side of the first trench and a second side of the first trench.

Abstract: Embodiments described herein relate to a substrate chucking apparatus having a plurality of cavities formed therein. The cavities are formed in a body of the chucking apparatus. In one embodiment, a first plurality of ports are formed in a chucking surface of the body and extend to a bottom surface of the body. In another embodiment, a second plurality of ports are formed in a bottom surface of the plurality of cavities and extend through the body to a bottom surface of the body.

Abstract: Embodiments described herein relate to methods and apparatus for performing immersion field guided post exposure bake processes. Embodiments of apparatus described herein include a chamber body defining a processing volume. A pedestal may be disposed within the processing volume and a first electrode may be coupled to the pedestal. A moveable stem may extend through the chamber body opposite the pedestal and a second electrode may be coupled to the moveable stem. In certain embodiments, a fluid containment ring may be coupled to the pedestal and a dielectric containment ring may be coupled to the second electrode.

Abstract: An electro-optical waveguide modulator device includes a seed layer on a substrate, the seed layer having a first crystallographic plane aligned with a surface of the seed layer, an electro-optical channel extending in a first direction on the seed layer and having a second crystallographic plane aligned with the surface of the seed layer, an insulator layer on both sides of the electro-optical channel on the substrate in a second direction perpendicular to the first direction, an electrode barrier layer on the electro-optical channel and the insulator layer, and one or more of electrodes extending in the second direction. The seed layer and the insulator layer each comprise material having a refractive index that is lower than the electro-optical channel.

Abstract: Aspects of the present disclosure relate generally to methods and apparatus of processing transparent substrates, such as glass substrates. In one implementation, a film stack for optical devices includes a glass substrate including a first surface and a second surface. The film stack includes a device function layer formed on the first surface, a hard mask layer formed on the device function layer, and a substrate recognition layer formed on the hard mask layer. The hard mask layer includes one or more of chromium, ruthenium, or titanium nitride. The film stack includes a backside layer formed on the second surface. The backside layer formed on the second surface includes one or more of a conductive layer or an oxide layer.

Abstract: Embodiments of the present disclosure generally relate to substrate support assemblies for retaining a surface of a substrate having one or more devices disposed on the surface without contacting the one or more devices and deforming the substrate, and a system having the same. In one embodiment, the substrate support assembly includes an edge ring coupled to a body of the substrate support assembly. A controller is coupled to actuated mechanisms of a plurality of pixels coupled to the body of the substrate support assembly such that portions of pixels corresponding to a portion of the surface of a substrate to be retained are positioned to support the portion without contacting one or more devices disposed on the surface of the substrate to be retained on the support surface.

Abstract: Embodiments of the disclosure relate to systems and methods for forming devices on a substrate. For example, a method for forming devices on a substrate can include projecting one or more ion beams from one or more ion beam chambers to form one or more devices on a first surface of a substrate and projecting one or more ion beams from one or more ion beam chambers to form one or more devices on a second surface of a substrate. In these embodiments, the first surface and the second surface are on opposite sides of the substrate. Therefore, the ion beams can form the devices on both sides of the substrate.

Abstract: Embodiments herein describe a sub-micron 3D diffractive optics element and a method for forming the sub-micron 3D diffractive optics element. In a first embodiment, a method is provided for forming a sub-micron 3D diffractive optics element on a substrate without planarization. The method includes depositing a material stack to be patterned on a substrate, depositing and patterning a thick mask material on a portion of the material stack, etching the material stack down one level, trimming a side portion of the thick mask material, etching the material stack down one more level, repeating trim and etch steps above ‘n’ times, and stripping the thick mask material from the material stack.

Abstract: Embodiments described herein relate to methods forming optical device structures. One embodiment of the method includes exposing a substrate to ions at an ion angle relative to a surface normal of a surface of the substrate to form an initial depth of a plurality of depths. A patterned mask is disposed over the substrate and includes two or more projections defining exposed portions of the substrate or a device layer disposed on the substrate. Each projection has a trailing edge at a bottom surface contacting the device layer, a leading edge at a top surface of each projection, and a height from the top surface to the device layer. Exposing the substrate to ions at the ion angle is repeated to form at least one subsequent depth of the plurality of depths.

Abstract: Embodiments described herein relate to methods forming optical device structures. One embodiment of the method includes exposing a substrate to ions at an ion angle relative to a surface normal of a surface of the substrate to form an initial depth of a plurality of depths. A patterned mask is disposed over the substrate and includes two or more projections defining exposed portions of the substrate or a device layer disposed on the substrate. Each projection has a trailing edge at a bottom surface contacting the device layer, a leading edge at a top surface of each projection, and a height from the top surface to the device layer. Exposing the substrate to ions at the ion angle is repeated to form at least one subsequent depth of the plurality of depths.

Abstract: Embodiments described herein relate to methods and apparatus for performing immersion field guided post exposure bake processes. Embodiments of apparatus described herein include a chamber body defining a processing volume. A pedestal may be disposed within the processing volume and a first electrode may be coupled to the pedestal. A moveable stem may extend through the chamber body opposite the pedestal and a second electrode may be coupled to the moveable stem. In certain embodiments, a fluid containment ring may be coupled to the pedestal and a dielectric containment ring may be coupled to the second electrode.

Abstract: A method for forming a device structure is disclosed. The method of forming the device structure includes forming a variable-depth structure in a device material layer using cyclic-etch process techniques. A plurality of device structures is formed in the variable-depth structure to define vertical or slanted device structures therein. The variable-depth structure and the vertical or slanted device structures are formed using an etch process.

Abstract: Aspects of the present disclosure relate generally to methods and apparatus of processing transparent substrates, such as glass substrates. In one implementation, a film stack for optical devices includes a glass substrate including a first surface and a second surface. The film stack includes a device function layer formed on the first surface, a hard mask layer formed on the device function layer, and a substrate recognition layer formed on the hard mask layer. The hard mask layer includes one or more of chromium, ruthenium, or titanium nitride. The film stack includes a backside layer formed on the second surface. The backside layer formed on the second surface includes one or more of a conductive layer or an oxide layer.

Abstract: Aspects of the present disclosure relate generally to methods and apparatus of processing transparent substrates, such as glass substrates. In one implementation, a film stack for optical devices includes a glass substrate including a first surface and a second surface. The film stack includes a device function layer formed on the first surface, a hard mask layer formed on the device function layer, and a substrate recognition layer formed on the hard mask layer. The hard mask layer includes one or more of chromium, ruthenium, or titanium nitride. The film stack includes a backside layer formed on the second surface. The backside layer formed on the second surface includes one or more of a conductive layer or an oxide layer.