Provided is a treatment liquid for a semiconductor with ruthenium including a ligand which coordinates to ruthenium, the treatment liquid is a treatment liquid for inhibiting a ruthenium-containing gas generated when contacting a semiconductor wafer including ruthenium with the treatment liquid in a semiconductor forming process. Also provided is an inhibitor for the generation of a ruthenium-containing gas, including a compound having a carbonyl group or a heterocyclic compound. Further provided is a treatment agent for a ruthenium-containing waste liquid, including a compound having a carbonyl group or a heterocyclic compound.

Embodiments of the present invention provide a method for removing a barrier layer of a metal interconnection on a wafer, which remove a single-layer metal ruthenium barrier layer. A method comprises: oxidizing step, is to oxidize the single-layer metal ruthenium barrier layer into a ruthenium oxide layer by electrochemical anodic oxidation process; oxide layer etching step, is to etch the ruthenium oxide layer with etching liquid to remove the ruthenium oxide layer. The present invention also provides a method for removing a barrier layer of a metal interconnection on a wafer, using in a structure of a process node of 10 nm and below, wherein the structure comprises a substrate, a dielectric layer, a barrier layer and a metal layer, the dielectric layer is deposited on the substrate and recessed areas are formed on the dielectric layer, the barrier layer is deposited on the dielectric layer, the metal layer is deposited on the barrier layer, wherein the metal layer is a copper layer, the barrier layer is a single-layer metal ruthenium layer, and the method comprises: thinning step, is to thin the metal layer; removing step, is to remove the metal layer; oxidizing step, is to oxidize the barrier layer, and the oxidizing step uses an electrochemical anodic oxidation process; oxide layer etching step, is to etch the oxidized barrier layer.

A substrate processing method includes a first oxidation step of heating a substrate at a first temperature by irradiation of light of a first intensity while supplying an oxygen gas or an ozone gas to the substrate, a first etching step of supplying an etching liquid to the substrate to make a surface layer of a molybdenum film that changed to molybdenum trioxide dissolve in the etching liquid, a second oxidation step of heating the substrate at a second temperature by irradiation of light of a second intensity while supplying the oxygen gas or the ozone gas to the substrate, and a second etching step of supplying the etching liquid to the substrate to make the surface layer of the molybdenum film that changed to the molybdenum trioxide dissolve in the etching liquid.

Provided is an etching solution composition that can have both a higher etch selectivity of silicon nitride and a reduction in the deposition of silica on the surface of silicon oxide. An inorganic acid-based etching solution composition for selectively etching away silicon nitride from a semiconductor containing silicon nitride and silicon oxide, the etching solution composition comprising: (a) an etch inhibitor that reduces etching of silicon oxide; and (b) a deposition inhibitor that reduces deposition of silica on a surface of silicon oxide.

Methods are provided for etching molybdenum in a wet ALE process. The methods disclosed herein use a wide variety of techniques and wet etch chemistries to oxidize a molybdenum surface and form a self-limiting, molybdenum oxide passivation layer in a surface modification step of the wet ALE process. In the wet ALE processes and methods disclosed herein, self-limiting behavior is provided in the oxidation step by adding a polydentate ligand to an aqueous oxidizing solution. The polydentate ligand reacts with and binds to the oxidized molybdenum surface to form a stable, ligand-molybdenum oxide complex, which is insoluble within the aqueous oxidizing solution. The insolubility of the ligand-molybdenum complex in the aqueous oxidizing solution provides self-limiting behavior in the oxidation step. After forming the molybdenum oxide passivation layer, the passivation layer is selectively removed in a dissolution step of the wet ALE process to etch the molybdenum surface.