A vaporization supply device includes a vaporizer for heating and vaporizing a liquid raw material L, a flow rate controller for controlling a flow rate of the gas supplied from the vaporizer to a gas supply destination, and a controller for heating the inside of the vaporizer to obtain a necessary gas flow rate, and performing a feedback control so that a pressure becomes equal to or higher than a predetermined value. The controller is configured so as to stop the feedback control at the time point when the flow rate control by the flow rate controller starts, then heat the liquid raw material by an amount of heat provided to the vaporizer more than the heat that has already been provided immediately before the feedback control ends, and change to the feedback control after a predetermined time has elapsed from the time point when the flow rate control by the flow rate controller starts.

Molybdenum-DAD precursors are described. Methods for depositing molybdenum-containing films on a substrate are described. The substrate is exposed to a molybdenum-DAD precursor and a reactant to form the molybdenum-containing film (e.g., elemental molybdenum, molybdenum oxide, molybdenum carbide, molybdenum silicide, molybdenum nitride). The exposures can be sequential or simultaneous.

Molybdenum-DAD precursors are described. Methods for depositing molybdenum-containing films on a substrate are described. The substrate is exposed to a molybdenum-DAD precursor and a reactant to form the molybdenum-containing film (e.g., elemental molybdenum, molybdenum oxide, molybdenum carbide, molybdenum silicide, molybdenum nitride). The exposures can be sequential or simultaneous.

An apparatus includes a chemical vapor deposition (CVD) reactor, an injector column that provides a metal organic precursor vapor into the CVD reactor, a heater in thermal communication with the injector column, and a control circuit configured to control the heater and thereby maintain the metal organic precursor vapor in the injector column above a saturation temperature. The control circuit may be configured to control the heater to maintain a temperature of the metal organic precursor vapor in the injector column in a temperature range from about 85 degrees Centigrade to about 200 degrees Centigrade. A temperature of the metal organic precursor vapor entering the injector column may be in a range from about 160 degrees Centigrade to about 200 degrees Centigrade and a pressure of the metal organic precursor vapor entering the injector column may be in a range from about 50 mbar to about 1000 mbar.

An apparatus includes a chemical vapor deposition (CVD) reactor, an injector column that provides a metal organic precursor vapor into the CVD reactor, a heater in thermal communication with the injector column, and a control circuit configured to control the heater and thereby maintain the metal organic precursor vapor in the injector column above a saturation temperature. The control circuit may be configured to control the heater to maintain a temperature of the metal organic precursor vapor in the injector column in a temperature range from about 85 degrees Centigrade to about 200 degrees Centigrade. A temperature of the metal organic precursor vapor entering the injector column may be in a range from about 160 degrees Centigrade to about 200 degrees Centigrade and a pressure of the metal organic precursor vapor entering the injector column may be in a range from about 50 mbar to about 1000 mbar.

A semiconductor manufacturing method using a semiconductor manufacturing apparatus 100 including a treating chamber 1, the method including: a first process of supplying a complexing gas into the treating chamber in which a wafer 2 having a surface having a transition metal-containing film formed thereon is placed, to adsorb an organic compound as a component of the complexing gas to the transition metal-containing film, the transition metal-containing film containing a transition metal element; and a second process of heating the wafer in which the organic compound is adsorbed to the transition metal-containing film, to react the organic compound with the transition metal element, thereby converting the organic compound into an organometallic complex, and desorbing the organometallic complex, wherein the organic compound has Lewis basicity, and is a multidentate ligand molecule capable of forming a bidentate or more coordination bond with the transition metal element.

A semiconductor manufacturing method using a semiconductor manufacturing apparatus 100 including a treating chamber 1, the method including: a first process of supplying a complexing gas into the treating chamber in which a wafer 2 having a surface having a transition metal-containing film formed thereon is placed, to adsorb an organic compound as a component of the complexing gas to the transition metal-containing film, the transition metal-containing film containing a transition metal element; and a second process of heating the wafer in which the organic compound is adsorbed to the transition metal-containing film, to react the organic compound with the transition metal element, thereby converting the organic compound into an organometallic complex, and desorbing the organometallic complex, wherein the organic compound has Lewis basicity, and is a multidentate ligand molecule capable of forming a bidentate or more coordination bond with the transition metal element.

Methods of forming ruthenium-containing films by pulsed chemical vapor deposition are provided. The methods include at least one deposition cycle. The deposition cycle includes pulsing a zerovalent Ru precursor with a carrier gas in the absence of a co-reactant onto a surface of a substrate, and delivering a purge gas to the surface of the substrate.

Methods of forming ruthenium-containing films by pulsed chemical vapor deposition are provided. The methods include at least one deposition cycle. The deposition cycle includes pulsing a zerovalent Ru precursor with a carrier gas in the absence of a co-reactant onto a surface of a substrate, and delivering a purge gas to the surface of the substrate.

Organometallic precursors and methods of depositing high purity metal films are discussed. Some embodiments utilize a method comprising exposing a substrate surface to an organometallic precursor comprising one or more of molybdenum (Mo), tungsten (W), osmium (Os), technetium (Tc), manganese (Mn), rhenium (Re) or ruthenium (Ru), and an iodine-containing reactant comprising a species having a formula RI.sub.x, where R is one or more of a C.sub.1-C.sub.10 alkyl, C.sub.3-C.sub.10 cycloalkyl, C.sub.2-C.sub.10 alkenyl, or C.sub.2-C.sub.10 alkynyl group, I is an iodine group and x is in a range of 1 to 4 to form a carbon-less iodine-containing metal film. Some embodiments advantageously provide methods of forming metal films having low carbon content (e.g., having greater than or equal to 95% metal species on an atomic basis), without using an oxidizing agent or a reductant.