Abstract: The disclosure provides a compensating design method for a shadow mask including: providing a first shadow mask having a first opening pattern and a first material pattern; disposing the first shadow mask on a substrate having a predetermined depositing film area with first and second sides; performing a deposition process by using the first shadow mask as a mask to form a film on an actual depositing film area, wherein the distance between the first and the third sides is a first bias, and the distance between the second and the fourth sides is a second bias, and a single side gray zone of the actual depositing film area relative to the predetermined depositing film area is substantially half of the sum of the first and the second biases; and designing a second shadow mask according to the single side gray zone.

Abstract: A method for forming an integrated circuit device including an interconnect structure, e.g., copper dual damascene. The method includes providing a substrate and forming an interlayer dielectric layer overlying the substrate. The method also includes patterning the interlayer dielectric layer to form a contact structure and forming a barrier metal layer overlying the contact structure. The method includes forming a seed layer comprising copper bearing species overlying the barrier metal layer and applying an oxygen bearing species to treat the seed layer to cause an oxide layer of predetermined thickness to form on the seed layer. The method protects the seed layer from contamination using the oxide layer while the substrate is transferred from the step of applying the seed layer and contacts a copper bearing material in liquid form overlying the oxide layer to dissolve the oxide layer while forming a thickness of copper bearing material using a plating process to begin filling the contact structure.

Abstract: A copper interconnect having a transition metal-silicon-nitride barrier (106). A transition metal-nitride is co-deposited with Si by reactive sputtering in a Si containing ambient to form barrier (106). The copper (110) is then deposited over the transition metal-silicon-nitride barrier (108) with good adhesion.

Abstract: A method for forming an integrated circuit device including an interconnect structure, e.g., copper dual damascene. The method includes providing a substrate and forming an interlayer dielectric layer overlying the substrate. The method also includes patterning the interlayer dielectric layer to form a contact structure and forming a barrier metal layer overlying the contact structure. The method includes forming a seed layer comprising copper bearing species overlying the barrier metal layer and applying an oxygen bearing species to treat the seed layer to cause an oxide layer of predetermined thickness to form on the seed layer. The method protects the seed layer from contamination using the oxide layer while the substrate is transferred from the step of applying the seed layer and contacts a copper bearing material in liquid form overlying the oxide layer to dissolve the oxide layer while forming a thickness of copper bearing material using a plating process to begin filling the contact structure.

Abstract: According to one embodiment, a broadcast/VOD receiver comprises a broadcast reception processing unit which selectively receives broadcast signals and reproduces content of broadcast programs, a VOD communication processing unit which communicates with a server providing VOD content to acquire the VOD content, an EPG information acquisition unit which acquires EPG information, a viewing reservation unit which makes reservations for viewing the VOD content to the server, a display data generation unit which creates a schedule table of the broadcast programs on the basis of the EPG information, adds list information columns displaying list information of the VOD content on the schedule table, and inserts viewing schedules corresponding to viewing reservations for the VOD content to the list information columns to generate display data, and a display processing unit which reproduces to output the display data and display the schedule table on a display screen of a display unit.

Abstract: A method of manufacturing a semiconductor device includes the steps of providing a semiconductor substrate (202), forming a dielectric layer (204) over the semiconductor substrate (202), and etching a trench or a via (206) in the dielectric layer (204) to expose a portion of the surface of the semiconductor substrate (202). The method also includes the step of forming a conductive layer (212, 220) within in the trench or the via (206). The method further includes the steps of polishing a portion of the conductive layer (220) and annealing the conductive layer (212, 220) at a predetermined temperature. Moreover, the conductive layer (212, 220) also includes a dopant, and the dopant diffuses substantially to the surface of the top side of the conductive layer (212, 220) to form a dopant oxide layer (212a, 220a) when the conductive layer (212, 220) is annealed at the predetermined temperature and the dopant is exposed to oxygen.

Abstract: A cassette for holding substrate in a load-lock comprising an outer casing having a front surface with multiple slots and two sidewalls having holes at the bottom section thereof. Braces are set at the corner edges inside the outer casing and side plates are attached to the braces. Each slot has a set of side plates attached to the braces for holding a substrate. Obstruction pieces are also set inside the outer casing near the corresponding holes. Each obstruction pieces comprise a fixed part and an obstructing part. The fixed part attaches firmly to a bottom plate of the outer casing, and the obstructing part blocks the corresponding hole on the outer casing.

Abstract: A cassette for holding substrate in a load-lock comprising an outer casing having a front surface with multiple slots and two sidewalls having holes at the bottom section thereof is provided. Braces are set at the corner edges inside the outer casing and side plates are attached to the braces. Each slot has a set of side plates attached to the braces for holding a substrate. Obstruction pieces are also set inside the outer casing near the corresponding holes. Each obstruction pieces comprise a fixed part and an obstructing part. The fixed part attaches firmly to a bottom plate of the outer casing, and the obstructing part blocks the corresponding hole on the outer casing.

Abstract: In an integrated device, a via is formed in a substrate layer and a barrier layer is formed on the substrate layer in the via. A seed layer is formed on the barrier layer in the via. The seed layer includes a first material and a second material. The first material provides an ability for the second material to maintain an adherence to the barrier layer.

Abstract: The structure and the fabrication method of an integrated circuit in the horizontal surface of a semiconductor body comprising a dielectric layer over said semiconductor body and a substantially vertical hole through the dielectric layer, the hole having sidewalls and a bottom. A barrier layer is positioned over the dielectric layer including the sidewalls within the hole and the bottom of the hole; the barrier layer is operable to seal copper. A copper-doped transition layer is positioned over the barrier layer; the transition layer has a resistivity higher than pure copper and is operable to strongly bond to copper and to the barrier layer, whereby electomigration reliability is improved. The remainder of said hole is filled with copper. The hole can be either a trench or a trench and a via.

Abstract: A method of manufacturing a semiconductor device includes the steps of providing a semiconductor substrate (202), forming a dielectric layer (204) over the semiconductor substrate (202), and etching a trench or a via (206) in the dielectric layer (204) to expose a portion of the surface of the semiconductor substrate (202). The method also includes the step of forming a conductive layer (212, 220) within in the trench or the via (206). The method further includes the steps of polishing a portion of the conductive layer (220) and annealing the conductive layer (212, 220) at a predetermined temperature. Moreover, the conductive layer (212, 220) also includes a dopant, and the dopant diffuses substantially to the surface of the top side of the conductive layer (212, 220) to form a dopant oxide layer (212a, 220a) when the conductive layer (212, 220) is annealed at the predetermined temperature and the dopant is exposed to oxygen.

Abstract: A method of manufacturing a semiconductor device includes the steps of providing a semiconductor substrate (202), forming a dielectric layer (204) over the semiconductor substrate (202), and etching a trench or a via (206) in the dielectric layer (204) to expose a portion of the surface of the semiconductor substrate (202). The method also includes the step of forming a conductive layer (212, 220) within in the trench or the via (206). The method further includes the steps of polishing a portion of the conductive layer (220) and annealing the conductive layer (212, 220) at a predetermined temperature. Moreover, the conductive layer (212, 220) also includes a dopant, and the dopant diffuses substantially to the surface of the top side of the conductive layer (212, 220) to form a dopant oxide layer (212a, 220a) when the conductive layer (212, 220) is annealed at the predetermined temperature and the dopant is exposed to oxygen.

Abstract: A cassette for holding substrate in a load-lock comprising an outer casing having a front surface with multiple slots and two sidewalls having holes at the bottom section thereof. Braces are set at the corner edges inside the outer casing and side plates are attached to the braces. Each slot has a set of side plates attached to the braces for holding a substrate. Obstruction pieces are also set inside the outer casing near the corresponding holes. Each obstruction pieces comprise a fixed part and an obstructing part. The fixed part attaches firmly to a bottom plate of the outer casing, and the obstructing part blocks the corresponding hole on the outer casing.

Abstract: The electroplating of copper is the leading technology for forming copper lines on integrated circuits. In the copper electroplating process a negative potential is applied to the semiconductor wafer with the surface of the semiconductor wafer acting as the cathode. The anode will be partially or wholly formed with copper. Both the anode and the semiconductor will be exposed to a solution comprising copper electrolytes. By reducing the temperature of the copper electrolytes solution below 25° C. the rate of self annealing grain growth will increase reducing the final resistively of the copper lines.

Abstract: The structure and the fabrication method of an integrated circuit in the horizontal surface of a semiconductor body comprising a dielectric layer over said semiconductor body and a substantially vertical hole through the dielectric layer, the hole having sidewalls and a bottom. A barrier layer is positioned over the dielectric layer including the sidewalls within the hole and the bottom of the hole; the barrier layer is operable to seal copper. A copper-doped transition layer is positioned over the barrier layer; the transition layer has a resistivity higher than pure copper and is operable to strongly bond to copper and to the barrier layer, whereby electomigration reliability is improved. The remainder of said hole is filled with copper. The hole can be either a trench or a trench and a via.

Abstract: The structure and the fabrication method of an integrated circuit in the horizontal surface of a semiconductor body comprising a dielectric layer over said semiconductor body and a substantially vertical hole through the dielectric layer, the hole having sidewalls and a bottom. A barrier layer is positioned over the dielectric layer including the sidewalls within the hole and the bottom of the hole; the barrier layer is operable to seal copper. A copper-doped transition layer is positioned over the barrier layer; the transition layer has a resistivity higher than pure copper and is operable to strongly bond to copper and to the barrier layer, whereby electomigration reliability is improved. The remainder of said hole is filled with copper. The hole can be either a trench or a trench and a via.

Abstract: In an integrated device, a via is formed in a substrate layer and a barrier layer is formed on the substrate layer in the via. A seed layer is formed on the barrier layer in the via. The seed layer includes a first material and a second material. The first material provides an ability for the second material to maintain an adherence to the barrier layer.

Abstract: The structure and the fabrication method of an integrated circuit in the horizontal surface of a semiconductor body comprising a dielectric layer over said semiconductor body and a substantially vertical hole through the dielectric layer, the hole having sidewalls and a bottom. A barrier layer is positioned over the dielectric layer including the sidewalls within the hole and the bottom of the hole; the barrier layer is operable to seal copper. A copper-doped transition layer is positioned over the barrier layer; the transition layer has a resistivity higher than pure copper and is operable to strongly bond to copper and to the barrier layer, whereby electomigration reliability is improved. The remainder of said hole is filled with copper. The hole can be either a trench or a trench and a via.

Abstract: A method of manufacturing a semiconductor device includes the steps of providing a semiconductor substrate (202), forming a dielectric layer (204) over the semiconductor substrate (202), and etching a trench or a via (206) in the dielectric layer (204) to expose a portion of the surface of the semiconductor substrate (202). The method also includes the step of forming a conductive layer (212, 220) within in the trench or the via (206). The method further includes the steps of polishing a portion of the conductive layer (220) and annealing the conductive layer (212, 220) at a predetermined temperature. Moreover, the conductive layer (212, 220) also includes a dopant, and the dopant diffuses substantially to the surface of the top side of the conductive layer (212, 220) to form a dopant oxide layer (212a, 220a) when the conductive layer (212, 220) is annealed at the predetermined temperature and the dopant is exposed to oxygen.

Abstract: A method of fabricating an integrated circuit. A thin liner (110, 210, 310) is deposited over dielectric layer including within a trench (108) and/or via (106). The thin liner (110, 210, 310) smoothes the sidewalls of the trench (108) and/or via (106) and reduces resistivity. The thin liner may comprise an organic or inorganic dielectric (110) or metal (210,310). A copper interconnect structure (116, 216, 316) is then formed over the thin liner (110, 210, 310).