The present invention relates to a substrate edge etching apparatus including: a substrate support assembly having a horizontally rotatable chuck base, chuck pins disposed on top of the chuck base, a purge gas inlet hole extending from an underside center of the chuck base to an interior of the chuck base, and a purge gas outlet hole extending radially from the purge gas inlet hole and then extending upwardly to penetrate top of the chuck base; a spin motor having a hollow tube-shaped driving shaft adapted to rotate the substrate support assembly; and a purge gas supply assembly connected to the driving shaft through a magnetic bearing in a state of not rotating, extending vertically from the underside center of the chuck base in a state of being spaced apart from an underside of the chuck base.

A substrate processing method includes forming a liquid film of an alkaline processing liquid on a substrate by supplying the alkaline processing liquid having a reduced oxygen concentration onto the substrate; and etching the substrate by rotating the substrate while supplying the alkaline processing liquid in a state that the liquid film having a given thickness is formed on the substrate.

Methods of manufacturing memory devices having memory cells and corresponding selectors, and associated systems and devices, are disclosed herein. In one embodiment, a method of manufacturing a memory device includes (a) removing a protection layer formed over the memory cells and (b) forming a cap layer over the memory cells before forming a conductive via through the memory device. The cap layer is configured to protect the memory cells during operation and can comprise a resistive material. The protection layer can be more efficiently removed with improved process margin and less device health impact using a polishing process before the conductive via is formed, thus increasing the manufacturing margin of the memory device.

Various embodiments of the present technology generally relate to semiconductor device architectures and manufacturing techniques. More specifically, some embodiments of the present technology relate to large area metrology and process control for anisotropic chemical etching. Catalyst influenced chemical etching (CICE) can be used to create high aspect ratio semiconductor structures with dimensions in the nanometer to millimeter scale with anisotropic and smooth sidewalls. However, all aspects of the CICE process must be compatible with the equipment used in semiconductor fabrication facilities today, and they must be scalable to enable wafer scale processing with high yield and reliability. This invention relates to metrology and control of etch and CMOS compatible methods of patterning the catalyst and removing it without damaging the etched structures.

The present application discloses a method for manufacturing semiconductor devices having gate dielectric layers at different thickness. The gate dielectric layers having other than the minimum thickness are respectively formed by the following steps: step 1: forming a first mask layer; step 2: etching the first mask layer to form a first opening; step 3: etching a semiconductor substrate at the bottom of the first opening to form a second groove; step 4: filling the second groove and the first opening with the second material layer; step 5: etching back the second material layer to form the gate dielectric layer, such that the second material layer is flush with the top surface of the semiconductor substrate; and step 6: removing the first mask layer.

A substrate processing apparatus includes a substrate holding section that holds a plurality of substrates, which form a substrate row, aligned in a row in a row direction, a processing tank that stores a processing liquid allowing the substrates held by the substrate holding section to be immersed in, and a plurality of bubble generating pipes that each supply a gas to the processing liquid to generate bubbles in the processing liquid. Of the plurality of bubble generating pipes, a flow rate of a gas supplied to an end bubble generating pipe located below an end of the substrate row immersed in the processing liquid differs from a flow rate of a gas supplied to a central bubble generating pipe located below a center of the substrate row.

A wafer cleaning apparatus is provided. The wafer cleaning apparatus includes comprising a chamber configured to be loaded with a wafer, a nozzle on the wafer and configured to provide liquid chemicals on an upper surface of the wafer, a housing under the wafer, a laser module configured to irradiate laser on the wafer, a transparent window disposed between the wafer and the laser module, and a controller configured to control on/off of the laser module, wherein the controller is configured to control repetition of turning the laser module on and off, and retain temperature of the wafer within a temperature range, and a ratio of time when the laser module is on in one cycle including on/off of the laser module is 30% to 50%.

A method of fabricating a high electron mobility transistor is disclosed. The method comprises using an ion implantation process to amorphize a portion of the barrier layer to a specific depth. The etch rate of this amorphized portion is much faster than that of the rest of the barrier layer. In this way, the depth of the recessed regions into which the source and drain contacts are disposed is more tightly controlled. Further, the etching process may be a wet or dry etch process. The roughness of the recessed region may also be improved using this approach.

A method of controlling a substrate etching process includes disposing a bottom surface or a top surface of a substrate adjacent to volume of etching fluid to produce an etchant-substrate interface and heating the etchant-substrate interface via spatially controlled electromagnetic radiation. The method also includes transmitting a monitoring beam through the substrate, the substrate and volume of etching fluid being at least partially transparent at the wavelength range of the monitoring beam and measuring a property of the substrate surface during the substrate etching process via the monitoring beam to produce a real-time measured property for the substrate. A corresponding etching system and computer-program product is also disclosed herein.

The present disclosure provides a photoresist stripping device and a photoresist stripping method. The photoresist stripping device including a conveyor belt, a liquid storage tank, a filtering device, a lighting device and a stripping tank. Through disposing a metal-organic framework (MOF) material in a filter element, the MOF material is configured to adsorb a dissolved oxygen of the stripping solution in a visible light environment, thereby reducing the difference in oxygen concentration between the inside and outside of the gap, and alleviating hollowing out phenomenon of copper caused by stripping the photoresist of the substrate. Further, when reaching a saturation step, can heat or emit ultraviolet light to release the dissolved oxygen to make the filter material recyclable.