A substrate liquid processing apparatus includes a liquid processing unit, a processing liquid circulating line, and a boiling state detecting unit provided in a processing bath of the liquid processing unit. The controller controls a supply pump of the processing liquid circulating line based on a signal from the boiling state detecting unit, and adjusts a pressure of a supplied phosphoric acid aqueous solution in a flow path so as to adjust the boiling state of the phosphoric acid aqueous solution to a desired state.

A cleaning system for processing a substrate after polishing includes a sulfuric peroxide mix (SPM) module, at least two cleaning elements, and a plurality of robots. The SPM module includes a sulfuric peroxide mix (SPM) cleaner having a first container to hold a sulfuric peroxide mix liquid and five to twenty first supports to hold five to twenty substrates in the liquid in the first container, and a rinsing station having a second container to hold a rinsing liquid and five to twenty second supports to hold five to twenty substrates in the liquid in the second container. Each of the at least two cleaning elements are configured to process a single substrate at a time. Examples of a cleaning element include a megasonic cleaner, a rotating brush cleaner, a buff pad cleaner, a jet spray cleaner, a chemical spin cleaner, a spin drier, and a marangoni drier.

A substrate treatment apparatus according to an embodiment includes: a tank configured to store a liquid chemical with which a plurality of substrates are treated; a piping having an ejection port that ejects the liquid chemical or bubbles into the tank; a plurality of rods that support the plurality of substrates in the tank; and a converter that is provided in the plurality of rods or the tank and that converts vibration applied to each substrate by the liquid chemical or the bubbles ejected from the piping into rotation in one direction around a center of the substrate as a rotational axis.

A semiconductor manufacturing apparatus according to the present embodiment includes a tank, a heater, a bubble supplier, a sensor and a controller. The tank stores a chemical solution for processing a substrate. The heater heats the chemical solution. The bubble supplier supplies bubbles to the chemical solution in the tank. The sensor detects at least one of a concentration of the chemical solution, a water concentration of the chemical solution, specific gravity of the chemical solution and a vapor concentration of a gas discharged from the tank. The controller controls the supply of bubbles by the bubble supplier based on a detection result of the sensor.

Provided are methods for fabricating transistors using a gate last approach. These methods involve etching of titanium nitride and titanium carbide structures while preserving high k-dielectric structures. The titanium carbide structures may also include aluminum. Etching may be performed in one or more etching solutions, each including hydrogen peroxide. Titanium nitride and titanium carbide structures can be etched simultaneously (non-selectively) in the same etching solution that also includes hydrochloric acid, in addition to hydrogen peroxide, and maintained at about 25° C. and 85° C. In some embodiments, titanium nitride structures and titanium carbide structures may be etched separately (selectively) in different operations and using different etching solutions. The titanium nitride structures may be etched in a diluted hydrogen peroxide solution maintained at about 25° C. and 85° C. The titanium carbide structures may be etched in a solution that also includes ammonium hydroxide, in addition to hydrogen peroxide, and maintained at about 25° C.

Various technologies are described herein pertaining to electrochemical etching of a semiconductor controlled by way of a laser that emits light with an energy below a bandgap energy of the semiconductor.

A method of debonding a substrate from a layer sequence includes a) providing a composite including a wafer with the substrate, the layer sequence applied to a growth surface of the substrate, and a sacrificial layer arranged between the substrate and the layer sequence, a carrier on a cover surface of the layer sequence facing away from the substrate, and at least two separating trenches extending in the vertical direction through the layer sequence and to and/or through the sacrificial layer, b) attaching a pumping device on the composite and forming a second direct flow path between the separating trenches and the pumping device, c) introducing the composite into an etching bath with an etching solution, d) generating a pressure gradient between separating trenches and the etching solution, and e) debonding the substrate.

According to embodiments, a substrate treatment apparatus includes a housing, a heater and a pipe. The housing stores solution containing phosphoric acid and houses a substrate including a silicon substrate. The heater heats the solution over a normal boiling point of the solution. The pipe supplies heated solution heated by the heater into the housing while generating air bubbles.

According to various embodiments, a method may include: filling a chamber and a tube coupled to the chamber with a first liquid, the tube extending upwards from the chamber; introducing a portion of a second liquid into the first liquid in the tube; and at least partially removing the first liquid from the chamber to empty the tube into the chamber so that a continuous surface layer from the introduced second liquid is provided on the first liquid in the chamber.

An etcher comprises a bath, a plurality of blades, and a tunnel. The bath includes a first electrode at a first end and a second electrode at a second end. The plurality of blades is configured to fit in the bath. At least one blade of the plurality of blades holds a wafer. At least one tunnel is configured to fit between adjacent blades of the plurality of blades in the bath.