Methods are provided for dual selective deposition of a first material on a first surface of a substrate and a second material on a second, different surface of the same substrate. The selectively deposited materials may be, for example, metal, metal oxide, or dielectric materials.

Methods are provided for dual selective deposition of a first material on a first surface of a substrate and a second material on a second, different surface of the same substrate. The selectively deposited materials may be, for example, metal, metal oxide, or dielectric materials.

Provided is a thin-film forming raw material containing a compound represented by the following formula (1):

##STR00001##

in the formula (1), R.sup.1 to R.sup.5 each independently represent a hydrogen atom, an alkyl group having 1 to 5 carbon atoms, or a group containing a fluorine atom, M represents a metal atom, and “n” represents a valence of the metal atom represented by M, provided that at least one of R.sup.2, R.sup.3, and R.sup.4 represents the group containing a fluorine atom.

Provided is a thin-film forming raw material containing a compound represented by the following formula (1):

##STR00001##

in the formula (1), R.sup.1 to R.sup.5 each independently represent a hydrogen atom, an alkyl group having 1 to 5 carbon atoms, or a group containing a fluorine atom, M represents a metal atom, and “n” represents a valence of the metal atom represented by M, provided that at least one of R.sup.2, R.sup.3, and R.sup.4 represents the group containing a fluorine atom.

A method of forming an electrode in accordance with an exemplary embodiment includes a process of forming a mask pattern on one surface of a base to expose a partial area of the one surface of the base by using a mask material that is polymer including an end tail having at least one bonding structure of covalent bond and double bond, a process of loading the base on which the mask pattern is formed into a chamber, and a process of forming a conductive layer containing copper on the exposed one surface of the base by using an atomic layer deposition method that alternately injects a source material containing copper and a reactive material that reacts with the source material into the chamber.

Thus, according to the method of forming an electrode in accordance with an exemplary embodiment, a thin-film caused by a material for forming an electrode is not formed on a surface of the mask pattern. Therefore, a residue is not remained when the mask pattern is removed to prevent a defect caused by the residue from being generated.

A method of forming an electrode in accordance with an exemplary embodiment includes a process of forming a mask pattern on one surface of a base to expose a partial area of the one surface of the base by using a mask material that is polymer including an end tail having at least one bonding structure of covalent bond and double bond, a process of loading the base on which the mask pattern is formed into a chamber, and a process of forming a conductive layer containing copper on the exposed one surface of the base by using an atomic layer deposition method that alternately injects a source material containing copper and a reactive material that reacts with the source material into the chamber.

Thus, according to the method of forming an electrode in accordance with an exemplary embodiment, a thin-film caused by a material for forming an electrode is not formed on a surface of the mask pattern. Therefore, a residue is not remained when the mask pattern is removed to prevent a defect caused by the residue from being generated.

Methods and precursors for selectively depositing a metal film on a silicon nitride surface relative to a silicon oxide surface are described. The substrate comprising both surfaces is exposed to a blocking compound to selectively block the silicon oxide surface. A metal film is then selectively deposited on the silicon nitride surface.

A semiconductor manufacturing apparatus includes: a stage installed inside a processing chamber and holding a semiconductor substrate having a high-k insulating film including silicate; and a gas supply line including a first system supplying reactive gas to the processing chamber and a second system supplying catalytic gas to the processing chamber, wherein mixed gas which includes complex forming gas reacting with a metal element included in the high-k insulating film to form a first volatile organometallic complex and complex stabilizing material gas increasing stability of the first organometallic complex is supplied as the reactive gas, and catalytic gas using a second organometallic complex, which modifies the high-k insulating film and promotes a formation reaction of the first organometallic complex, as a raw material is supplied.

A semiconductor manufacturing apparatus includes: a stage installed inside a processing chamber and holding a semiconductor substrate having a high-k insulating film including silicate; and a gas supply line including a first system supplying reactive gas to the processing chamber and a second system supplying catalytic gas to the processing chamber, wherein mixed gas which includes complex forming gas reacting with a metal element included in the high-k insulating film to form a first volatile organometallic complex and complex stabilizing material gas increasing stability of the first organometallic complex is supplied as the reactive gas, and catalytic gas using a second organometallic complex, which modifies the high-k insulating film and promotes a formation reaction of the first organometallic complex, as a raw material is supplied.

The system and method includes the suspension of a free-standing carbon article within a reaction chamber, the introduction of the chemical precursor in a reaction environment within the chamber, and heating of the carbon article in the presence of the chemical precursor leading to deposition in a site-specific manner.