This disclosure relates to the process of etching and treatment of side walls while processing microdevices. One aspect is to fill the device wall indentation with a polymer. The disclosure relates to a method and device with its structure to the process of etching and treatment of sidewalls. The methods of etching, coating, and curing are used.

A method and alignment system for minimizing errors in the deposition of films of tailored thickness. A first position on a stage is identified for optimal placement of a downward looking microscope (DLM) and an upward looking microscope (ULM) when alignment marks on the DLM and ULM are aligned, where the DLM is attached to a bridge and the ULM is attached to the stage. A second position on the stage is identified when the ULM on the stage is aligned with the alignment marks on a metrology tool. A surface of a chucked substrate affixed to the stage is then measured. A map between a substrate coordinate system and a metrology coordinate system may then be obtained using the measured surface of the chucked substrate with the first and second positions.

Provided is an atomic-smooth device with a microstructure. The device includes, from the bottom to top, a substrate, a bonding material, a second dielectric layer on the substrate, the microstructure, and a first dielectric layer, where a surface of the first dielectric layer is an atomic-smooth surface. Further provided is a method for preparing an atomic-smooth device with a microstructure to effectively avoid pits or burrs generated when the existing microstructure is machined.

A method for manufacturing semiconductor structure includes: providing a substrate having a first surface; forming a trench on the first surface, wherein a bottom surface and side walls of the substrate are configured along an outer periphery of the trench; annealing the substrate with high-purity argon or high-purity hydrogen to flatten the bottom surface and the side walls; conformally disposing a composite-material layer to cover the first surface, the bottom surface and the side walls; disposing a polysilicon material layer in the trench; removing the composite-material layer on the first surface; forming a multi-layer metal interconnection structure on the first surface and the polysilicon material layer, the multi-layer metal interconnection structure including a MEMS frame structure and through holes; removing the polysilicon material layer and the composite-material layer; using plasma treatment to the trench to flatten the bottom surface and the side walls. The plasma contains inert gas and hydrogen.

A method for manufacturing semiconductor structure includes: providing a substrate having a first surface; forming a trench on the first surface, wherein a bottom surface and side walls of the substrate are configured along an outer periphery of the trench; annealing the substrate with high-purity argon or high-purity hydrogen to flatten the bottom surface and the side walls; conformally disposing a composite-material layer to cover the first surface, the bottom surface and the side walls; disposing a polysilicon material layer in the trench; removing the composite-material layer on the first surface; forming a multi-layer metal interconnection structure on the first surface and the polysilicon material layer, the multi-layer metal interconnection structure including a MEMS frame structure and through holes; removing the polysilicon material layer and the composite-material layer; using plasma treatment to the trench to flatten the bottom surface and the side walls. The plasma contains inert gas and hydrogen.

An apparatus may include a superstrate. The superstrate can include a body having a diameter. The body may fit within a projected square. The projected square may have a length equal to the diameter of the body. The body within the projected square may produce an open area between an exterior edge of the body and the projected square. The superstrate may further include a first projection extending from the exterior edge of the body within the open area.

A laser micro-machining process called laser-assisted material phase-change and expulsion (LAMPE) micromachining that includes cutting features in a cutting surface of a piece of material using a pulsed laser with intensity, pulse width and pulse rate set to melt and eject liquid material without vaporizing said material, or, in the case of silicon, create an ejectible silicon oxide. Burrs are removed from the cutting surface by electro-polishing the cutting surface with a dilute acid solution using an electric potential higher than a normal electro-polishing electric potential. A multi-lamina assembly of laser-micro-machined laminates (MALL) may utilize MEMS. In the MALL process, first, the individual layers of a micro-electromechanical system (MEMS) are fabricated using the LAMPE micro-machining process. Next, the fabricated microstructure laminates are stack assembled and bonded to fabricate MEM systems. The MALL MEMS fabrication process enables greater material section and integration, greater design flexibility, low-cost manufacturing, rapid development, and integrated packaging.

A flattening apparatus includes a mold holding unit configured to suck and hold a mold including a flat portion, a substrate holding unit holding a substrate, an exposure unit irradiating a light curing composition supplied onto the substrate with light at least via the mold to cure the composition, the composition being irradiated with the light and cured in a state where the flat portion of the mold is in contact with the composition on the substrate, a gas suction unit sucking gas from a spatial region between the mold and the mold holding unit, a gas supply unit supplying the gas to the spatial region, and a control unit controlling the gas suction unit and the gas supply unit to perform temperature adjustment processing for supplying the gas to the spatial region in a state where the mold is sucked and held onto the mold holding unit.

A process for forming inkjet nozzle devices on a frontside surface of a wafer substrate. The process includes the steps of: (i) providing the wafer substrate having a plurality of etched holes defined in the frontside surface, each etched hole being filled with first and second polymers such that the second polymer is coplanar with the frontside surface; (ii) forming the inkjet nozzle devices on the frontside surface using MEMS fabrication steps; and (iii) removing the first and second polymers via oxidative ashing, wherein first and second polymers are different.

A planarization structure is formed with a planar upper face enclosing a relief projecting from a planar substrate. The process used deposits a layer of a first material over the reliefs and then forms a layer of a second material with a planar upper face. This second material may be etched selectively with respect to the first material. The second layer is processed so that the protuberances of the first material are uncovered. A planarizing is then performed on the first material as far as the layer of the second material by selective chemical-mechanical polishing with respect to the second material.