Abstract: A vacuum processing apparatus is provided with: a vacuum processing tank; a first gas introduction section that is constructed such that a first processing gas in a radical state is introduced into the vacuum processing tank and is guided to a semiconductor wafer; and a second gas introduction section that is constructed such that a second processing gas that reacts with the first processing gas is introduced into the vacuum processing tank and is guided to the semiconductor wafer. The second gas introduction section has two shower nozzles provided at positions on either side of an introduction pipe provided for the first gas introduction section. According to this vacuum processing apparatus, high speed processing of a number of processing objects can be achieved. Moreover, the in-plane uniformity of the processing objects after processing can be ensured.

Abstract: In a method and an apparatus for forming layers on substrates, a plurality of substrates is supported by a boat in a processing chamber, and a processing gas is supplied into the processing chamber through a nozzle pipe. The processing gas supplied into processing chamber is excited in plasma state by microwave energy applied through a microwave antenna, and thus layers having uniform thickness may be formed on the substrates by the excited processing gas in the plasma state.

Abstract: In a gas supplying apparatus used to form a layer on a substrate, a liquid reactant is introduced into an atomizer through a liquid mass flow controller and an on-off valve. An aerosol mist formed by the atomizer is introduced into a vaporizer and then vaporized. The on-off valve is coupled with the atomizer and controlled by a valve controller of the liquid mass flow controller. The on-off valve is opened to form the layer and closed during downtime of a layer formation apparatus to prevent leakage of the remaining liquid reactant in a connecting conduit between the liquid mass flow controller and the on-off valve.

Abstract: A method of forming a titanium nitride layer by an atomic layer deposition process using a batch-type vertical reaction furnace is described wherein a first source gas including a titanium precursor is provided onto substrates loaded in a process chamber for a first time period; a first purge gas is introduced into the process chamber for a second time period shorter than the first time period; a second source gas including nitrogen is provided onto the substrates for a third time period substantially identical to the first time period; and, a second purge gas is introduced into the process chamber for a fourth time period substantially identical to the second time period. Titanium nitride layers having uniform thickness and good step coverage may thus be formed while realizing a greatly reduced manufacturing time.

Abstract: A method of forming titanium nitride layers by an atomic layer deposition process using a batch-type vertical reaction furnace is described wherein the titanium nitride layers are formed on one or more substrates in accordance with a reaction between a first source gas including TiCl4 gas and a second source gas including an NH3 gas. After forming the titanium nitride layers, chlorine remaining in the titanium nitride layers is removed using a treatment gas which includes an NH3 gas. The substrates are revolved by a predetermined rotation angle between repeated titanium nitride layer formation cycles. The process of forming the titanium nitride layers and rotating the substrates is alternately repeated resulting in titanium nitride layers having substantially uniform thicknesses and low specific resistance.

Abstract: A vacuum processing apparatus is provided with: a vacuum processing tank; a first gas introduction section that is constructed such that a first processing gas in a radical state is introduced into the vacuum processing tank and is guided to a semiconductor wafer; and a second gas introduction section that is constructed such that a second processing gas that reacts with the first processing gas is introduced into the vacuum processing tank and is guided to the semiconductor wafer. The second gas introduction section has two shower nozzles provided at positions on either side of an introduction pipe provided for the first gas introduction section. According to this vacuum processing apparatus, high speed processing of a number of processing objects can be achieved. Moreover, the in-plane uniformity of the processing objects after processing can be ensured.