Semiconductor structures and method for forming the same are provided. The semiconductor structure includes a fin protruding from a substrate and a gate stack formed across the fin. The semiconductor structure further includes a first cap layer formed over the gate stack and a source/drain structure formed adjacent to the gate stack in the fin. The semiconductor structure further includes a contact structure formed over the source/drain structure and a second cap layer formed over the contact structure. In addition, the first cap layer and the second cap layer include different halogens.

A pattern-forming method includes applying a first composition on a surface layer of a substrate to form a first coating film. The surface layer includes a first region which includes a metal atom, and a second region which includes a silicon atom. The first coating film is heated. A portion other than a portion formed on the first region or a portion other than a portion formed on the second region of the first coating film heated is removed, thereby forming a first lamination portion. A second composition is applied on the substrate on which the first lamination portion is formed to form a second coating film. The second coating film is heated or exposed. A portion other than a portion formed on the first lamination portion of the second coating film heated or exposed is removed, thereby forming a second lamination portion.

A method for manufacturing a semiconductor memory includes: providing a portion to be processed, and performing a preset process step on the portion to be processed at least after a minimum waiting time; before performing the preset process step, performing a thermal oxidation process on the portion to be processed; and before performing the preset process step, performing a cleaning process, the cleaning process being used to remove oxides from the surface of the portion to be processed, the oxides being wholly or partly generated by the thermal oxidation process.

Methods for removing a passivation film from a copper surface can include exposing the passivation film to a vapor phase organic reactant, for example at a temperature of 100 C. to 400 C. In some embodiments, the passivation film may have been formed by exposure of the copper surface to benzotriazole, such as can occur during a chemical mechanical planarization process. The methods can be performed as part of a process for integrated circuit fabrication. A second material can be selectively deposited on the cleaned copper surface relative to another surface of the substrate.

A method for processing a product layer includes providing a dielectric layer over a substrate, etching to remove a portion of the dielectric layer, forming a product layer over the etched dielectric layer, and removing the product layer by providing a dissolving solution and using the dissolving solution to rinse or soak the product layer to dissolve the product layer.

Methods of depositing a film selectively onto a first material relative to a second material are described. The substrate is pre-cleaned by heating the substrate to a first temperature, cleaning contaminants from the substrate and activating the first surface to promote formation of a self-assembled monolayer (SAM) on the first material. A SAM is formed on the first material by repeated cycles of SAM molecule exposure, heating and reactivation of the first material. A final exposure to the SAM molecules is performed prior to selectively depositing a film on the second material. Apparatus to perform the selective deposition are also described.

A method of cleaning an epitaxial reaction chamber in-situ is disclosed. The method may include a pre-coating step, a high temperature baking step, and a gas etching step. The method is able to remove residue buildup within the reaction chamber, which may be made of quartz.

In some aspects, methods of forming a metal sulfide thin film are provided. According to some methods, a metal sulfide thin film is deposited on a substrate in a reaction space in a cyclical process where at least one cycle includes alternately and sequentially contacting the substrate with a first vapor-phase metal reactant and a second vapor-phase sulfur reactant. In some aspects, methods of forming a three-dimensional architecture on a substrate surface are provided. In some embodiments, the method includes forming a metal sulfide thin film on the substrate surface and forming a capping layer over the metal sulfide thin film. The substrate surface may comprise a high-mobility channel.

Methods for removing a passivation film from a copper surface can include exposing the passivation film to a vapor phase organic reactant, for example at a temperature of 100 C. to 400 C. In some embodiments, the passivation film may have been formed by exposure of the copper surface to benzotriazole, such as can occur during a chemical mechanical planarization process. The methods can be performed as part of a process for integrated circuit fabrication. A second material can be selectively deposited on the cleaned copper surface relative to another surface of the substrate.

A method for forming a semiconductor structure is provided. The method includes patterning a semiconductor substrate to form a semiconductor fin, forming a source/drain structure on the semiconductor fin, forming a gate electrode layer across the semiconductor fin, forming a first halogen-containing metal cap layer on the gate electrode layer, forming a contact structure on the source/drain structure and connected to the source/drain structure, and forming a second halogen-containing metal cap layer on the contact structure. The first halogen-containing metal cap layer and the second halogen-containing metal cap layer include different halogens.