Abstract: A semiconductor device includes a substrate with both a compressive layer and an aluminum nitride tensile layer overlying at least a portion of the substrate. The aluminum nitride tensile layer is configured to counteract the compressive layer stress in the device to thereby control an amount of substrate bow in the device. The device includes a temperature-sensitive material supported by the substrate, in which the temperature-sensitive material has a relatively low thermal degradation temperature. The aluminum nitride tensile layer is formed at a temperature below the thermal degradation temperature of the temperature-sensitive material.

Abstract: A semiconductor device includes a substrate with both a compressive layer and an aluminum nitride tensile layer overlying at least a portion of the substrate. The aluminum nitride tensile layer is configured to counteract the compressive layer stress in the device to thereby control an amount of substrate bow in the device. The device includes a temperature-sensitive material supported by the substrate, in which the temperature-sensitive material has a relatively low thermal degradation temperature. The aluminum nitride tensile layer is formed at a temperature below the thermal degradation temperature of the temperature-sensitive material.

Abstract: A semiconductor device has a substrate with both compressive and tensile layers deposited overlying a single major surface (face) of the device. The tensile layer may be deposited directly on the substrate of the device, with the compressive layer overlying the tensile layer. A transition material may be located between the tensile layer and the compressive layer. The transition material may be a compound including the components of one or both of the tensile layer and the compressive layer. In a specific embodiment, the tensile material may be a silicon nitride, the compressive layer may be a silicon oxide, and the transition material may be a silicon oxy-nitride, which may be formed by oxidizing the surface of the tensile silicon nitride layer. By depositing both tensile and compressive layers on the same face of the device the opposite major surface (face) is free for processing.

Abstract: A semiconductor device has a substrate with both compressive and tensile layers deposited overlying a single major surface (face) of the device. The tensile layer may be deposited directly on the substrate of the device, with the compressive layer overlying the tensile layer. A transition material may be located between the tensile layer and the compressive layer. The transition material may be a compound including the components of one or both of the tensile layer and the compressive layer. In a specific embodiment, the tensile material may be a silicon nitride, the compressive layer may be a silicon oxide, and the transition material may be a silicon oxy-nitride, which may be formed by oxidizing the surface of the tensile silicon nitride layer. By depositing both tensile and compressive layers on the same face of the device the opposite major surface (face) is free for processing.

Abstract: A cathode for a cluster tool in accordance with the present invention includes a base, a disc-shaped target mounted to the base and a magnetic source for establishing magnetic flux lines through the target. The target further comprises a top plate with a plurality of through holes; and a bottom plate with a plurality of bottom plate openings which interconnect distribution grooves formed in one surface with base face channels formed in the other surface. When the top plate is mated to the bottom plate, a path of fluid communication is established from the base face channels to the through holes to allow for inert gas to pass through the target. During operation, the through holes act as micro-cathodes to more efficiently cause material to be sputtered from the target. Each through hole defines a through hole axis, and the magnetic flux lines are parallel with the through holes axes.

Abstract: A cathode for a cluster tool in accordance with the present invention includes a base, a disc-shaped target mounted to the base and a magnetic source for establishing magnetic flux lines through the target. The target further comprises a top plate with a plurality of through holes; and a bottom plate with a plurality of bottom plate openings which interconnect distribution grooves formed in one surface with base face channels formed in the other surface. When the top plate is mated to the bottom plate, a path of fluid communication is established from the base face channels to the through holes to allow for inert gas to pass through the target. During operation, the through holes act as micro-cathodes to more efficiently cause material to be sputtered from the target. Each through hole defines a through hole axis, and the magnetic flux lines are parallel with the through holes axes.

Abstract: An electrical field between a positive anode and a negative target in a cavity and a magnetic field in the cavity cause electrons from the target to ionize neutral gas (e.g. argon) atoms in the cavity. The ions cause the target to release sputtered atoms (e.g. aluminum) for deposition on a substrate. A shield between the target and the substrate inhibits charged particle movement to the substrate. The anode potential may be positive, and the shield and the magnetic members may be grounded, to obtain electron movement to the anode, thereby inhibiting the heating of the shield and the magnetic members by electron impingement. The anode may be water cooled. The magnitude of the positive anode voltage relative to the target voltage provides selectively for (a) a uniform thickness of sputtered atoms on the walls of a groove in the substrate or (b) a filling of the groove by the sputtered atoms and a uniform thickness of deposition on the substrate surface including the filled groove.

Abstract: A dual wafer position loadlock chamber for a cluster tool includes a block which defines the chamber, a platen that projects into the chamber, a heat lamp assembly that radiates into the loadlock chamber and a plurality of rails for positioning a wafer within the chamber. The platen selectively cools the wafer and includes a bell portion located within the loadlock chamber. The heat lamp assembly is mounted to the block across the chamber from the bell portion. The rails extend into the loadlock chamber around the bell portion, and an upper flange and lower flange extend perpendicularly from each rail. During cooling operations, the wafer is placed on the upper flanges, which positions the wafer immediately proximate the bell portion for cooling the wafer. During degassing operations, the wafer is placed on the lower flanges and the heat lamp assembly illuminates and establishes a focal plane of uniform radiation intensity which is co-planar with the wafer.

Abstract: A conductive adhesion layer (e.g. titanium 150 .ANG. thick) is formed on a substrate. A first conductive barrier layer (e.g. high-density gold-colored titanium-nitride 300 .ANG. thick) having properties of microcracking in a first direction to relieve inherent stress is deposited on the conductive adhesion layer. A second conductive barrier layer (e.g. low-density brown-colored titanium-nitride 400 .ANG. thick) having properties of low inherent stress is deposited on the first barrier layer. The second barrier layer may be exposed to air, thereby further inhibiting the leakage to the substrate of material from a conductive layer (e.g. aluminum silicon copper or aluminum copper) when a third barrier layer (e.g. high-density gold-colored titanium nitride 300 .ANG. thick) and such conductive layer are thereafter sequentially deposited on the second barrier layer. Such method may be used to provide a substantially uniform deposition on the walls of a groove for receiving a via. An insulating coating (e.g.

Abstract: An electrical field between a positive anode and a negative target in a cavity and a magnetic field in the cavity cause electrons from the target to ionize neutral gas (e.g. argon) atoms in the cavity. The ions cause the target to release sputtered atoms (e.g. aluminum) for deposition on a substrate. A shield between the target and the substrate inhibits charged particle movement to the substrate. The anode potential may be positive, and the shield and the magnetic members may be negative relative to the anode, to obtain electron movement to the anode, thereby inhibiting the heating of the shield and the magnetic members by electron impingement. The anode may be water cooled. The magnitude of the positive anode voltage relative to the target voltage provides selectively for (a) a uniform thickness of sputtered atoms on the walls of a groove in the substrate or (b) a filling of the groove by the sputtered atoms and a uniform thickness of deposition on the substrate surface including the filled groove.

Abstract: A target releases electrons to an anode through a cavity containing gaseous atoms (e.g. argon) having properties of becoming ionized by electron impingement. Magnetic and electrical fields increase the distance of electron travel between the anode and the target, thereby enhancing ion formation from the gaseous atoms. The ions bombard the target and cause it to emit sputtered atoms (e.g. aluminum) which are deposited on a substrate (e.g. wafer) displaced from the target. In one embodiment, a shield disposed between the target and the substrate is shaped, and has a potential, to attract charged particles and prevent them from moving to the substrate. This allows the wafer to be disposed close to the target, thereby enhancing the density, and the thickness uniformity, of the deposition on the substrate. The shield also acts as a getter to remove impurities (e.g. water molecules) from the space between the target and the substrate.