The cleaning apparatus includes multiple kinds of cleaning modules each configured to perform a cleaning processing of a substrate, a first accommodating section configured to accommodate the multiple kinds of cleaning modules therein, and a fluid supply section configured to supply a fluid to the cleaning modules accommodated in the first accommodating section through a pipe. Each of the multiple kinds of cleaning modules includes a pipe connection portion having a common connection position to be connected with the pipe.

A method for forming an overlap transistor includes forming a gate structure over a III-V material, wet cleaning the III-V material on side regions adjacent to the gate structure and plasma cleaning the III-V material on the side regions adjacent to the gate structure. The III-V material is plasma doped on the side regions adjacent to the gate structure to form plasma doped extension regions that partially extend below the gate structure.

A cleaning apparatus is provided. This cleaning apparatus includes an inlet, an outlet, a first conveyance path, a second conveyance path, a cleaning unit disposed on the first conveyance path and configured to clean the target object in a non-contacting manner, and a drying unit disposed on the first conveyance path and configured to dry the target object in a non-contacting manner. The first conveyance path and the second conveyance path are vertically arranged side by side. The second conveyance path is positioned above the first conveyance path and connected with the outlet at an end point. The second conveyance path functions as a stocker configured to temporarily store the target object.

Disclosed is a method of adjusting a concentration of a chemical liquid in a treatment liquid, the method including: treating a substrate by supplying a treatment liquid stored in a main tank from a nozzle in a heated state to the substrate, and recovering the treatment liquid used in the treatment of the substrate to the main tank directly or via still another tank, and then reusing the recovered treatment liquid, a concentration adjustment operation of adjusting a concentration of the treatment liquid in the main tank is performed in a standby time period in which the substrate is not treated with the treatment liquid, and the concentration adjustment operation is performed by discharging the treatment liquid in a heated state from the nozzle to evaporate a part of the diluting solution, and recovering the discharged treatment liquid to the main tank.

Embodiments of the disclosed technology include patterning a graphene sheet for biosensor and electronic applications using lithographic patterning techniques. More specifically, the present disclosure is directed towards the method of patterning a graphene sheet with a hard mask metal layer. The hard mask metal layer may include an inert metal, which may protect the graphene sheet from being contaminated or damaged during the patterning process.

Exemplary methods of forming a semiconductor structure may include etching a via through a semiconductor structure to expose a first circuit layer interconnect metal. The methods may include forming a layer of a material overlying the exposed first circuit layer interconnect metal. The methods may also include forming a barrier layer within the via having minimal coverage along the bottom of the via. The methods may additionally include forming a second circuit layer interconnect metal overlying the layer of material.

Methods of enhancing selective deposition are described. In some embodiments, a blocking layer is deposited on a metal surface before deposition of a dielectric. In some embodiments, a metal surface is functionalized to enhance or decrease its reactivity.

Metallic layers can be selectively deposited on one surface of a substrate relative to a second surface of the substrate. In some embodiments, the metallic layers are selectively deposited on a first metallic surface relative to a second surface comprising silicon. In some embodiments the reaction chamber in which the selective deposition occurs may optionally be passivated prior to carrying out the selective deposition process. In some embodiments selectivity of above about 50% or even about 90% is achieved.

Methods of forming semiconductor devices by enhancing selective deposition are described. In some embodiments, a blocking layer is deposited on a metal surface before deposition of a barrier layer. A substrate with a metal surface, a dielectric surface and an aluminum oxide surface has a blocking layer deposited on the metal surface using an alkylsilane.

Deposits such as particles deposited on a surface of a target object can be easily removed while suppressing damage to the target object such as destruction of pattern formed on the surface of the target object or film roughness on the surface of the target object. In a pre-treatment, vapor of a hydrogen fluoride is supplied to a wafer W to dissolve a natural oxide film 11, so that a deposit 10 attached to a surface of the natural oxide film 11 is slightly separated from a surface of the wafer W. A carbon dioxide gas that does not react with an underlying film 12 is supplied to a processing gas atmosphere where the wafer W is placed, so that a gas cluster of the carbon dioxide gas is generated. Then, the gas cluster in a non-ionized state is irradiated toward the wafer W to remove the deposit 10.