This disclosure provides systems, methods, and apparatus related to graphene. In one aspect, a method includes submerging a frame support in an etching solution that is contained in a container. A growth substrate, a graphene sheet disposed on the growth substrate, and a primary support disposed on the graphene sheet is placed on a surface of the etching solution. The growth substrate is dissolved in the etching solution to leave the graphene sheet and the primary support floating on a surface of the etching solution. The etching solution in the container is replaced with a washing solution. The washing solution is removed from the container so that the graphene sheet becomes disposed on the frame support.

Embodiments of a plug for use in an electrostatic chuck are provided herein. In some embodiments, a plug for use in an electrostatic chuck includes a polymer sleeve having a central opening; and a core disposed in the central opening of the polymer sleeve, the core having a central protrusion and a peripheral ledge, wherein an outer surface of the core includes a helical channel extending from a lower surface of the core towards the peripheral ledge to at least partially define a gas flow path through the plug, and wherein the peripheral ledge is disposed between an upper surface of the polymer sleeve and the lower surface of the core.

The present disclosure relates to a stage apparatus comprising: an object table configured to hold a substrate, the object table comprising an electrode configured to be charged by a power source and an electrical connection configured to electrically connect the electrode to the power source, and an electric field shield configured to shield at least a part of the electrical connection.

A method for processing scanning electron microscope specimen is provided. The method comprises: providing a specimen to be observed; providing a carbon nanotube array comprising a plurality of carbon nanotubes; and pulling a carbon nanotube film from the carbon nanotube array, and laying the carbon nanotube film on a surface of the specimen, wherein the carbon nanotube film comprising a plurality of through holes.

A plasma processing apparatus in which a radio-frequency power supply modulates radio-frequency power such that the level of the radio-frequency power in a first period is higher than the level of the radio-frequency power in a second period. The second period alternates with the first period. A bias power supply modulates bias energy such that the level of the bias energy in a third period is higher than the level of the bias energy in a fourth period. The fourth period alternates with the third period. The bias power supply adjusts the time difference between the start point of the first period and the start point of the third period which partially overlaps with the first period according to the power coupling efficiency of the radio-frequency power to the plasma, obtained from a power of a traveling wave and a power of a reflected wave.

A plasma processing device includes an inductively coupled plasma antenna including an input end and an output end, a series circuit including an additional inductor and a variable capacitor connected in series, and a controller that varies a capacitance of the variable capacitor. The input terminal is connected via an antenna matching device to an antenna power supply. The output terminal is connected to the additional inductor. The additional inductor is connected via the variable capacitor to ground.

A sample attachment device includes a mount, a mounted depression, and a pressure release depression. Liquid and air bubbles can pass the pressure release depression. The mounted depression is on the mount. A cartridge is mounted on the mounted depression. The pressure release depression is in the mounted depression. The pressure release depression is vertically under the cartridge when the cartridge is mounted on the mounted depression.

A method for fabricating calcite channels in a nanofluidic device is described. A porous membrane is attached to a substrate. Calcite is deposited in porous openings in the porous membrane attached to the substrate. A width of openings in the deposited calcite is in a range from 50 to 100 nanometers (nm). The porous membrane is etched to remove the porous membrane from the substrate to form a fabricated calcite channel structure. Each channel has a width in the range from 50 to 100 nm.

A performance of a sample holder 1 used in a charged particle beam device is improved. A shield plate 2 is connected to a sample stand 7. A sample stand 7 is provided with a pressing member 5 that can move in a direction perpendicular to the shield plate 2 in a state in which the pressing member is attached to the sample stand 7, and has a bar shape. A sample supporting member 4 connected to the pressing member 5 is provided at a position facing the shield plate 2. A spring 6 is provided along an outer circumference of the pressing member 5 and is connected to the sample supporting member 4 and the sample stand 7.

A sample cartridge carrier apparatus is coupled with a focused ion beam processing apparatus (FIB processing apparatus). A guide mechanism is configured to guide a series of movements of a sample cartridge holder to allow a sample cartridge to be held by a carrier base on a sub stage. Sub cooling equipment is configured to cool the sample cartridge via the sub stage. A carrier mechanism carries the carrier base between the sub stage and a main stage.