According to one embodiment, a gas supply pipe has a first gas pipe configured to blow a gas which has flowed from an inflow opening via first gas blow holes arranged along a longitudinal direction, and a second gas pipe provided in parallel with the first gas pipe. The second gas pipe has second gas blow holes arranged along the longitudinal direction, and allows the gas to flow in a direction opposite to the first gas pipe.

Disclosed is a substrate treating apparatus comprising a wafer chuck on which a substrate is placed, an injector unit on a side of the wafer chuck and injecting process gases that include a first gas and a second gas, and a gas supply unit supplying the process gases to the injector unit. The gas supply unit comprises first and second gas supply sources that respectively accommodate the first and second gases, first and second gas supply lines that respectively connect the first and second gas supply sources to the injector unit, and first and second heating units that are respectively disposed on the first and second gas supply lines. The first heating units disposed on the first gas supply line have a density per unit length greater than the density per unit length of the second heating units disposed on the second gas supply line.

Disclosed is a substrate treating apparatus comprising a wafer chuck on which a substrate is placed, an injector unit on a side of the wafer chuck and injecting process gases that include a first gas and a second gas, and a gas supply unit supplying the process gases to the injector unit. The gas supply unit comprises first and second gas supply sources that respectively accommodate the first and second gases, first and second gas supply lines that respectively connect the first and second gas supply sources to the injector unit, and first and second heating units that are respectively disposed on the first and second gas supply lines. The first heating units disposed on the first gas supply line have a density per unit length greater than the density per unit length of the second heating units disposed on the second gas supply line.

Disclosed is a substrate treating apparatus comprising a wafer chuck on which a substrate is placed, an injector unit on a side of the wafer chuck and injecting process gases that include a first gas and a second gas, and a gas supply unit supplying the process gases to the injector unit. The gas supply unit comprises first and second gas supply sources that respectively accommodate the first and second gases, first and second gas supply lines that respectively connect the first and second gas supply sources to the injector unit, and first and second heating units that are respectively disposed on the first and second gas supply lines. The first heating units disposed on the first gas supply line have a density per unit length greater than the density per unit length of the second heating units disposed on the second gas supply line.

Disclosed is a substrate treating apparatus comprising a wafer chuck on which a substrate is placed, an injector unit on a side of the wafer chuck and injecting process gases that include a first gas and a second gas, and a gas supply unit supplying the process gases to the injector unit. The gas supply unit comprises first and second gas supply sources that respectively accommodate the first and second gases, first and second gas supply lines that respectively connect the first and second gas supply sources to the injector unit, and first and second heating units that are respectively disposed on the first and second gas supply lines. The first heating units disposed on the first gas supply line have a density per unit length greater than the density per unit length of the second heating units disposed on the second gas supply line.

A system and method for providing support to semiconductor wafer is provided. An embodiment comprises introducing a vacancy enhancing material during the formation of a semiconductor ingot prior to the semiconductor wafer being separated from the semiconductor ingot. The vacancy enhancing material forms vacancies at a high density within the semiconductor ingot, and the vacancies form bulk micro defects within the semiconductor wafer during high temperature processes such as annealing. These bulk micro defects help to provide support and strengthen the semiconductor wafer during subsequent processing and helps to reduce or eliminate a fingerprint overlay that may otherwise occur.

Gas-phase reactor systems and methods suitable for use with precursors that are solid phase at room temperature and pressure are disclosed. The systems and methods as described herein can be used to, for example, form amorphous, polycrystalline, or epitaxial layers (e.g., one or more doped semiconductor layers) on a surface of a substrate.

The present invention provides a method for doping carbon in a thin film on a wafer, the method comprising the steps of: arranging a thin film-formed wafer in a processing area; supplying an atmospheric gas into the processing area to bring the pressure in the processing area to a process pressure higher than atmospheric pressure; heating the processing area to bring the temperature in the processing area to a processing temperature; and supplying a source gas containing carbon to the processing area to allow the source gas to undergo a chemical reaction with the thin film under the process pressure at the process temperature, thereby injecting the carbon into the thin film.

An atomic layer deposition apparatus includes a chamber including a plurality of regions; and a heating device respectively providing specific temperature ranges for the plurality of regions. By flowing precursor gases at different flow rates in the different regions, thin films can be simultaneously formed in the different regions having different film thicknesses.