Provided are a silicon nitride film etching composition, a method of etching a silicon nitride film using the same, and a manufacturing method of a semiconductor device. Specifically, a silicon nitride film may be stably etched with a high selection ratio relative to a silicon oxide film, and when the composition is applied to an etching process at a high temperature and a semiconductor manufacturing process, not only no precipitate occurs but also anomalous growth in which the thickness of the silicon oxide film is rather increased does not occur, thereby minimizing defects and reliability reduction.

A composition for selectively etching a layer including an aluminum compound in the presence of a layer of a low-k material and/or a layer including copper and/or cobalt, and a corresponding process, are described. Further described is a process for the manufacture of a semiconductor device, including the step of selectively etching at least one layer including an aluminum compound in the presence of a layer of a low-k material and/or a layer including copper and/or cobalt by contacting the at least one layer including an aluminum compound with the described composition.

A composition for selectively etching a layer including an aluminum compound in the presence of a layer of a low-k material and/or a layer including copper and/or cobalt, and a corresponding process, are described. Further described is a process for the manufacture of a semiconductor device, including the step of selectively etching at least one layer including an aluminum compound in the presence of a layer of a low-k material and/or a layer including copper and/or cobalt by contacting the at least one layer including an aluminum compound with the described composition.

Etchant solutions, pretreatment and methods for etching electroless nickel on metallic materials are provided herein. More specifically, etchant solutions for selectively removing electroless nickel from the surface of metallic materials containing copper, and optionally as containing stainless steel, methods of etching and pretreatment are provided.

Methods for etching alkali metal compounds are disclosed. Some embodiments of the disclosure expose an alkali metal compound to an alcohol to form a volatile metal alkoxide. Some embodiments of the disclosure expose an alkali metal compound to a ?-diketone to form a volatile alkali metal ?-diketonate compound. Some embodiments of the disclosure are performed in-situ after a deposition process. Some embodiments of the disclosure provide methods which selectively etch alkali metal compounds.

Methods for etching alkali metal compounds are disclosed. Some embodiments of the disclosure expose an alkali metal compound to an alcohol to form a volatile metal alkoxide. Some embodiments of the disclosure expose an alkali metal compound to a ?-diketone to form a volatile alkali metal ?-diketonate compound. Some embodiments of the disclosure are performed in-situ after a deposition process. Some embodiments of the disclosure provide methods which selectively etch alkali metal compounds.

The present disclosure discloses an etching composition. The etching composition includes: a component A: oxidizing agent 1-30 wt %; a component B: inorganic acid 0.5-20 wt %; a component C: organic acid 0-15 wt %; a component D: chelating agent 0.01-15 wt %; a component E: ionic compound and/or other inorganic acids except the inorganic acid in the component B 0-0.1 wt %; and deionized water.

The present disclosure discloses an etching composition. The etching composition includes: a component A: oxidizing agent 1-30 wt %; a component B: inorganic acid 0.5-20 wt %; a component C: organic acid 0-15 wt %; a component D: chelating agent 0.01-15 wt %; a component E: ionic compound and/or other inorganic acids except the inorganic acid in the component B 0-0.1 wt %; and deionized water.

A substrate processing apparatus includes a substrate processing unit and a controller. The substrate processing unit is configured to perform an etching processing on one or more substrates each having a silicon nitride film and a silicon oxide film on a surface thereof with a processing liquid containing a phosphoric acid aqueous solution and a silicic acid compound. The controller is configured to control individual components of the substrate processing apparatus. The controller includes a concentration control unit configured to control a phosphoric acid concentration of the processing liquid such that etching selectivity of the silicon nitride film with respect to the silicon oxide film falls within a given range from a beginning of the etching processing to an end thereof.

A substrate processing apparatus includes a substrate processing unit and a controller. The substrate processing unit is configured to perform an etching processing on one or more substrates each having a silicon nitride film and a silicon oxide film on a surface thereof with a processing liquid containing a phosphoric acid aqueous solution and a silicic acid compound. The controller is configured to control individual components of the substrate processing apparatus. The controller includes a concentration control unit configured to control a phosphoric acid concentration of the processing liquid such that etching selectivity of the silicon nitride film with respect to the silicon oxide film falls within a given range from a beginning of the etching processing to an end thereof.