A screen includes a framework of a first material having one or more openings therethrough defining a fluidic filter, and a substance of a second material positioned within the one or more openings in the framework and configured to be removable from the framework during an electrochemical reaction.

An electroplating etching apparatus includes a power to output current, and a container configured to contain an electrolyte. A cathode is coupled to the container and configured to fluidly communicate with the electrolyte. An anode is electrically connected to the output, and includes a graphene layer. A metal substrate layer is formed on the graphene layer, and is etched from the graphene layer in response to the current flowing through the anode.

An electroplating etching apparatus includes a power to output current, and a container configured to contain an electrolyte. A cathode is coupled to the container and configured to fluidly communicate with the electrolyte. An anode is electrically connected to the output, and includes a graphene layer. A metal substrate layer is formed on the graphene layer, and is etched from the graphene layer in response to the current flowing through the anode.

Methods and apparatuses for delaminating workpieces are provided. In one or more aspects, a method can include processing or otherwise delaminating the workpiece by separating a delamination stack and a support substrate disposed thereon. The workpiece that can include a sacrificial layer disposed between the delamination stack and the support substrate. The method can include exposing at least a portion of the workpiece to an electrolyte solution, applying an electrical current through the sacrificial layer and the electrolyte solution, selectively removing the electrically conductive or semiconductive material from the sacrificial layer during an etching process, and separating the delamination stack and the support substrate one from the other. The delamination stack can include a process piece that can be one or more wafers or devices (e.g., thin-film devices) or one or more portions of the one or more wafers or devices.

Methods and apparatuses for delaminating workpieces are provided. In one or more aspects, a method can include processing or otherwise delaminating the workpiece by separating a delamination stack and a support substrate disposed thereon. The workpiece that can include a sacrificial layer disposed between the delamination stack and the support substrate. The method can include exposing at least a portion of the workpiece to an electrolyte solution, applying an electrical current through the sacrificial layer and the electrolyte solution, selectively removing the electrically conductive or semiconductive material from the sacrificial layer during an etching process, and separating the delamination stack and the support substrate one from the other. The delamination stack can include a process piece that can be one or more wafers or devices (e.g., thin-film devices) or one or more portions of the one or more wafers or devices.

Provided are a diamond composite body capable of shortening a separation time for separating a substrate and a diamond layer, the substrate, and a method for manufacturing a diamond, as well as a diamond obtained from the diamond composite body and a tool including the diamond. The diamond composite body includes a substrate including a diamond seed crystal and having grooves in a main surface, a diamond layer formed on the main surface of the substrate, and a non-diamond layer formed on a substrate side at a constant depth from an interface between the substrate and the diamond layer.

Provided are a diamond composite body capable of shortening a separation time for separating a substrate and a diamond layer, the substrate, and a method for manufacturing a diamond, as well as a diamond obtained from the diamond composite body and a tool including the diamond. The diamond composite body includes a substrate including a diamond seed crystal and having grooves in a main surface, a diamond layer formed on the main surface of the substrate, and a non-diamond layer formed on a substrate side at a constant depth from an interface between the substrate and the diamond layer.

Provided herein is a method for preparing MXenes, such as Ti.sub.2CT.sub.x, Cr.sub.2CT.sub.x, and V.sub.2CT.sub.x, products prepared therefrom, and compositions and devices including the same.

Provided herein is a method for preparing MXenes, such as Ti.sub.2CT.sub.x, Cr.sub.2CT.sub.x, and V.sub.2CT.sub.x, products prepared therefrom, and compositions and devices including the same.

Provided are a diamond composite body capable of shortening a separation time for separating a substrate and a diamond layer, the substrate, and a method for manufacturing a diamond, as well as a diamond obtained from the diamond composite body and a tool including the diamond. The diamond composite body includes a substrate including a diamond seed crystal and having grooves in a main surface, a diamond layer formed on the main surface of the substrate, and a non-diamond layer formed on a substrate side at a constant depth from an interface between the substrate and the diamond layer.