Abstract: Methods for depositing a metal layer on an integrated circuit device comprising providing a transition metal precursor, carrier gas and hydrogen gas to a deposition chamber such that the partial pressure of the precursor and carrier gas exceeds about 0.25 Torr and the partial pressure of hydrogen gas exceeds about 2.5 Torr are disclosed. Methods of forming a cobalt layer on an integrated circuit device are also disclosed.

Abstract: A metal contact in a semiconductor device is formed by forming an insulating layer having a contact hole therein on a silicon substrate. A cobalt layer is formed on a bottom and inner walls of the contact hole. A cobalt silicide layer is formed at the bottom of the contact hole while forming a titanium layer on the cobalt layer. A plug is formed on the titanium layer so as to fill the contact hole.

Abstract: A metal contact in a semiconductor device is formed by forming an insulating layer having a contact hole therein on a silicon substrate. A cobalt layer is formed on a bottom and inner walls of the contact hole. A cobalt silicide layer is formed at the bottom of the contact hole while forming a titanium layer on the cobalt layer. A plug is formed on the titanium layer so as to fill the contact hole.

Abstract: Contacts having different characteristics may be created by forming a first silicide layer over a first device region of a substrate, and then forming a second silicide layer over a second device region while simultaneously further forming the first silicide layer. A first contact hole may be formed in a dielectric layer over a first device region of a substrate. A silicide layer may then be formed in the first contact hole. A second contact hole may be formed after the first contact hole and silicide layer is formed. A second silicidation may then be performed in the first and second contact holes.

Abstract: The present invention provides methods for forming cobalt silicide layers, including introducing a vaporized cobalt precursor onto a silicon substrate to form a cobalt layer. The vaporized cobalt precursor has the formula Co2(CO)6(R1—C?C—R2), wherein R1 is H or CH3, and R2 is H, t-butyl, methyl or ethyl. The silicon substrate is thermally treated so that silicon is reacted with cobalt to form a cobalt silicide layer. Methods for manufacturing semiconductor devices including the cobalt silicide layers described herein and such devices are also provided.

Abstract: The present invention provides methods of forming cobalt layers on a structure comprising forming a preliminary cobalt layer on a semiconductor substrate by introducing an organic metal precursor onto the semiconductor substrate and treating a surface of the preliminary cobalt layer under an atmosphere of a hydrogen-containing gas to remove impurities contained in the preliminary cobalt layer. Compositions of cobalt layers are also provided. Further provided are semiconductor devices comprising cobalt layers provided herein.

Abstract: TiN layer structures for semiconductor devices, methods of forming TiN layer structures, semiconductor devices having TiN layer structures and methods of fabricating semiconductor devices are disclosed. The TiN layer structure for a semiconductor device includes a TiN base layer and a conductive capping layer. The TiN base layer is formed on a substrate. The conductive capping layer is formed on the TiN base layer by laminating unit layers repeatedly.

Abstract: The present invention provides methods for forming cobalt silicide layers, including introducing a vaporized cobalt precursor onto a silicon substrate to form a cobalt layer. The vaporized cobalt precursor has the formula Co2(CO)6(R1—C?C—R2), wherein R1 is H or CH3, and R2 is H, t-butyl, methyl or ethyl. The silicon substrate is thermally treated so that silicon is reacted with cobalt to form a cobalt silicide layer. Methods for manufacturing semiconductor devices including the cobalt silicide layers described herein and such devices are also provided.

Abstract: An integrated circuit device, e.g., a memory device, includes a substrate, a first insulation layer on the substrate, and a contact pad disposed in the first insulation layer in direct contact with the substrate. A second insulation layer is disposed on the first insulation layer. A conductive pattern, e.g., a damascene bit line, is disposed in the second insulation layer. A conductive plug extends through the second insulation layer to contact the contact pad and is self-aligned to the conductive pattern. An insulation film may separate the conductive pattern and the conductive plug. A glue layer may be disposed between the conductive pattern and the second insulation layer. The device may further include a third insulation layer on the second insulation layer and the conductive pattern, and the conductive plug may extend through the second and third insulation layers.

Abstract: Methods of forming metal nitride layers on a substrate include reacting a metal source gas with a nitrogen source gas in a process chamber to form a metal nitride layer on the substrate. The process chamber may have an atmosphere having a pressure of about 0.1 mTorr to about 5 mTorr and a temperature of about 200° C. to about 450° C. A ratio of the flow rate of the metal source gas to the flow rate of the nitrogen source gas may be “1” or more. An interlayer insulating layer may be formed on the semiconductor substrate prior to formation of the metal nitride layer.

Abstract: An integrated circuit device, e.g., a memory device, includes a substrate, a first insulation layer on the substrate, and a contact pad disposed in the first insulation layer in direct contact with the substrate. A second insulation layer is disposed on the first insulation layer. A conductive pattern, e.g., a damascene bit line, is disposed in the second insulation layer. A conductive plug extends through the second insulation layer to contact the contact pad and is self-aligned to the conductive pattern. An insulation film may separate the conductive pattern and the conductive plug. A glue layer may be disposed between the conductive pattern and the second insulation layer. The device may further include a third insulation layer on the second insulation layer and the conductive pattern, and the conductive plug may extend through the second and third insulation layers.

Abstract: A method of forming a metal layer on the conductive region of a semiconductor device includes concurrently supplying a mixture gas including a hydrogen gas and a metal chloride compound gas, and a purge gas into a chamber having a sealed space for a predetermined time, thereby forming a first metal layer on the semiconductor substrate, using a plasma enhanced chemical vapor deposition (PECVD) method. The hydrogen gas and metal chloride gases are thereafter alternately supplied for a predetermined time while the purge gas is continuously supplied into the chamber, thereby forming a second metal layer on the first metal layer, using a PECVD method. Deterioration of semiconductor devices due to high heat by a conventional CVD method can be prevented using a PECVD method as a low temperature process, thereby improving a production yield.

Abstract: A method of fabricating an integrated circuit capacitor includes forming a first metal layer on a conductive plug in an interlayer insulating layer on a substrate. At least a portion of the first metal layer is silicided to form a metal silicide layer and a remaining first metal layer on the conductive plug. The remaining first metal layer is removed using a dry etching process. A lower electrode including a second metal layer is then formed on the metal silicide layer. Because the remaining first metal layer is removed, etching and/or other damage to the conductive plug and/or the interlayer insulating layer during a subsequent wet ethching process may be reduced and/or prevented.

Abstract: A metal contact in a semiconductor device is formed by forming an insulating layer having a contact hole therein on a silicon substrate. A cobalt layer is formed on a bottom and inner walls of the contact hole. A cobalt silicide layer is formed at the bottom of the contact hole while forming a titanium layer on the cobalt layer. A plug is formed on the titanium layer so as to fill the contact hole.

Abstract: The present invention provides methods for forming cobalt silicide layers, including introducing a vaporized cobalt precursor onto a silicon substrate to form a cobalt layer. The vaporized cobalt precursor has the formula Co2(CO)6(R1—C?C—R2), wherein R1 is H or CH3, and R2 is H, t-butyl, methyl or ethyl. The silicon substrate is thermally treated so that silicon is reacted with cobalt to form a cobalt silicide layer. Methods for manufacturing semiconductor devices including the cobalt silicide layers described herein and such devices are also provided.

Abstract: The present invention provides methods of forming cobalt layers on a structure comprising forming a preliminary cobalt layer on a semiconductor substrate by introducing an organic metal precursor onto the semiconductor substrate and treating a surface of the preliminary cobalt layer under an atmosphere of a hydrogen-containing gas to remove impurities contained in the preliminary cobalt layer. Compositions of cobalt layers are also provided. Further provided are semiconductor devices comprising cobalt layers provided herein.

Abstract: After a processing chamber is used to deposit a refractory metal film on a substrate, the chamber is plasma-treated with a gas including either nitrogen and/or hydrogen and in-situ cleaned. By plasma-treating the chamber with a gas including nitrogen, the refractory metal film that forms on interior surfaces of the chamber during substrate processing is nitrided. The nitrided refractory metal film can be removed from the chamber during the in-situ cleaning. By plasma-treating the chamber with a gas including hydrogen, reaction by-products generated in the chamber is diluted removed. The chamber may be plasma-treated in a gas ambient including both nitrogen and hydrogen. Also, the plasma treatment may be performed before and after the in-situ cleaning.

Abstract: Methods and compositions for depositing a metal layer on a integrated circuit device comprising a transition metal precursor and carrier gas such that a partial pressure of the precursor and carrier gas exceeds about 0.25 Torr are disclosed. Processes for the preparation of depositing a cobalt precursor on an integrated circuit device are also disclosed.

Abstract: An integrated circuit device, e.g., a memory device, includes a substrate, a first insulation layer on the substrate, and a contact pad disposed in the first insulation layer in direct contact with the substrate. A second insulation layer is disposed on the first insulation layer. A conductive pattern, e.g., a damascene bit line, is disposed in the second insulation layer. A conductive plug extends through the second insulation layer to contact the contact pad and is self-aligned to the conductive pattern. An insulation film may separate the conductive pattern and the conductive plug. A glue layer may be disposed between the conductive pattern and the second insulation layer. The device may further include a third insulation layer on the second insulation layer and the conductive pattern, and the conductive plug may extend through the second and third insulation layers.

Abstract: A metal contact in a semiconductor device is formed by forming an insulating layer having a contact hole therein on a silicon substrate. A cobalt layer is formed on a bottom and inner walls of the contact hole. A cobalt silicide layer is formed at the bottom of the contact hole while forming a titanium layer on the cobalt layer. A plug is formed on the titanium layer so as to fill the contact hole.