Abstract: Exemplary integrated cluster tools may include a factory interface including a first transfer robot. The tools may include a wet clean system coupled with the factory interface at a first side of the wet clean system. The tools may include a load lock chamber coupled with the wet clean system at a second side of the wet clean system opposite the first side of the wet clean system. The tools may include a first transfer chamber coupled with the load lock chamber. The first transfer chamber may include a second transfer robot. The tools may include a second transfer chamber coupled with the first transfer chamber. The second transfer chamber may include a third transfer robot. The tools may include a metal deposition chamber coupled with the transfer chamber.

Abstract: Exemplary integrated cluster tools may include a factory interface including a first transfer robot. The tools may include a wet clean system coupled with the factory interface at a first side of the wet clean system. The tools may include a load lock chamber coupled with the wet clean system at a second side of the wet clean system opposite the first side of the wet clean system. The tools may include a first transfer chamber coupled with the load lock chamber. The first transfer chamber may include a second transfer robot. The tools may include a dry etch chamber coupled with the first transfer chamber. The tools may include a second transfer chamber coupled with the first transfer chamber. The second transfer chamber may include a third transfer robot. The tools may include a process chamber coupled with the second transfer chamber.

Abstract: Semiconductor devices (e.g., GAA device structures) and processing methods and cluster tools for forming GAA device structures are described. The cluster tools for forming GAA device structures comprise a first etch chamber, a second etch chamber, and a third etch chamber. Each of the first etch chamber and the second etch chamber independently comprises a single-wafer chamber or an immersion chamber. One or more of the first etch chamber or the second etch chamber may be a wet etch chamber. In some embodiments, at least one of the first etch chamber, the second etch chamber, and the third etch chamber is a dry etch chamber. The cluster tool described herein advantageously reduces the number of cleaning processes, the total time between cleaning and processing operations, variations in time between processing and variation in sidewall loss compared to conventional cluster tools.

Abstract: Exemplary integrated cluster tools may include a factory interface including a first transfer robot. The tools may include a wet clean system coupled with the factory interface at a first side of the wet clean system. The tools may include a load lock chamber coupled with the wet clean system at a second side of the wet clean system opposite the first side of the wet clean system. The tools may include a first transfer chamber coupled with the load lock chamber. The first transfer chamber may include a second transfer robot. The tools may include a thermal treatment chamber coupled with the first transfer chamber. The tools may include a second transfer chamber coupled with the first transfer chamber. The second transfer chamber may include a third transfer robot. The tools may include a metal deposition chamber coupled with the second transfer chamber.

Abstract: Exemplary integrated cluster tools may include a factory interface including a first transfer robot. The tools may include a wet clean system coupled with the factory interface at a first side of the wet clean system. The tools may include a load lock chamber coupled with the wet clean system at a second side of the wet clean system opposite the first side of the wet clean system. The tools may include a first transfer chamber coupled with the load lock chamber. The first transfer chamber may include a second transfer robot. The tools may include a dry etch chamber coupled with the first transfer chamber. The tools may include a second transfer chamber coupled with the first transfer chamber. The second transfer chamber may include a third transfer robot. The tools may include a process chamber coupled with the second transfer chamber.

Abstract: Processing methods may be performed to produce semiconductor structures that include a high-k dielectric material. The methods include pre-cleaning a semiconductor substrate surface. An interfacial layer is formed on the substrate surface by exposing the substrate to an oxidizing atmosphere and thermally annealing the surface. The interfacial layer is treated with hydration chemistry to form a treated interfacial layer, followed by deposition of a high-k dielectric layer on the treated interfacial layer.

Abstract: Exemplary integrated cluster tools may include a factory interface including a first transfer robot. The tools may include a wet clean system coupled with the factory interface at a first side of the wet clean system. The tools may include a load lock chamber coupled with the wet clean system at a second side of the wet clean system opposite the first side of the wet clean system. The tools may include a first transfer chamber coupled with the load lock chamber. The first transfer chamber may include a second transfer robot. The tools may include a second transfer chamber coupled with the first transfer chamber. The second transfer chamber may include a third transfer robot. The tools may include a metal deposition chamber coupled with the transfer chamber.

Abstract: A substrate cleaning system to remove particulates from multiple substrates includes a cleaning tank for applying a cleaning liquid to substrates, a rinse tank for applying a rinsing liquid to substrates, and a robot system. The cleaning tank includes a stationary lid, an input lid, and an output lid. The input and output lids allow a substrate carrier designed to carry an individual substrate to access an inner volume of the cleaning tank for processing. A transport system moves the substrate in the substrate carrier through the inner volume of the cleaning tank by creating a series of gaps between substrates to allow proper processing. The robot system transports substrates through the input and output lids of the cleaning tank, and transports substrates into the rinse tank.

Abstract: A substrate cleaning system to remove particulates from multiple substrates includes a cleaning tank for applying a cleaning liquid to substrates, a rinse tank for applying a rinsing liquid to substrates, and a robot system. The cleaning tank includes a stationary lid, an input lid, and an output lid. The input and output lids allow a substrate carrier designed to carry an individual substrate to access an inner volume of the cleaning tank for processing. A transport system moves the substrate in the substrate carrier through the inner volume of the cleaning tank by creating a series of gaps between substrates to allow proper processing. The robot system transports substrates through the input and output lids of the cleaning tank, and transports substrates into the rinse tank.

Abstract: A method for removing particulates from a plurality of substrates includes opening a first access port in a top of a first container holding a cleaning fluid bath, inserting a first substrate through the first access port to a first support, closing the first access port, opening a second access port in the top of the first container, inserting a second substrate through the second access port to a second support, closing the second access port, opening the first access port, removing the first substrate through the first access port and delivering the first substrate into a rinsing station, closing the first access port, opening the second access port, removing the second substrate through the second access port and delivering the second substrate into the rinsing station, and closing the second access port.

Abstract: A substrate cleaning system to remove particulates from multiple substrates includes a cleaning tank for applying a cleaning liquid to substrates, a rinse tank for applying a rinsing liquid to substrates, and a robot system. The cleaning tank includes a stationary lid, an input lid, and an output lid. The input and output lids allow a substrate carrier designed to carry an individual substrate to access an inner volume of the cleaning tank for processing. A transport system moves the substrate in the substrate carrier through the inner volume of the cleaning tank by creating a series of gaps between substrates to allow proper processing. The robot system transports substrates through the input and output lids of the cleaning tank, and transports substrates into the rinse tank.

Abstract: Cleaning chambers may include a substrate support having a substrate seating position. The cleaning chambers may include a plurality of fluid nozzles facing the substrate support. Each fluid nozzle of the plurality of fluid nozzles may define a fluid port characterized by a leading edge and a trailing edge. Each fluid nozzle of the plurality of fluid nozzles may be angled relative to the substrate seating position of the substrate support to produce an interior angle of greater than or about 90° at an intersection location across the substrate seating position for a fluid delivered from each fluid nozzle at the leading edge of the fluid port.

Abstract: Forming an integrated circuit, for example by first, concurrently forming a first front end of line (FEOL) layer having a first thickness and a surface contacting or facing a semiconductor substrate frontside and a second FEOL layer, having a second thickness and including a same material as the first FEOL layer and having a surface contacting or facing a semiconductor substrate backside, and second, processing the second FEOL layer to reduce the second thickness.

Abstract: Forming an integrated circuit, for example by first, concurrently forming a first front end of line (FEOL) layer having a first thickness and a surface contacting or facing a semiconductor substrate frontside and a second FEOL layer, having a second thickness and including a same material as the first FEOL layer and having a surface contacting or facing a semiconductor substrate backside, and second, processing the second FEOL layer to reduce the second thickness.

Abstract: Semiconductor devices (e.g., GAA device structures) and processing methods and cluster tools for forming GAA device structures are described. The cluster tools for forming GAA device structures comprise a first etch chamber, a second etch chamber, and a third etch chamber. Each of the first etch chamber and the second etch chamber independently comprises a single-wafer chamber or an immersion chamber. One or more of the first etch chamber or the second etch chamber may be a wet etch chamber. In some embodiments, at least one of the first etch chamber, the second etch chamber, and the third etch chamber is a dry etch chamber. The cluster tool described herein advantageously reduces the number of cleaning processes, the total time between cleaning and processing operations, variations in time between processing and variation in sidewall loss compared to conventional cluster tools.

Abstract: A method for removing particulates from a plurality of substrates includes opening a first access port in a top of a first container holding a cleaning fluid bath, inserting a first substrate through the first access port to a first support, closing the first access port, opening a second access port in the top of the first container, inserting a second substrate through the second access port to a second support, closing the second access port, opening the first access port, removing the first substrate through the first access port and delivering the first substrate into a rinsing station, closing the first access port, opening the second access port, removing the second substrate through the second access port and delivering the second substrate into the rinsing station, and closing the second access port.

Abstract: A cleaning system for processing a substrate after polishing includes a sulfuric peroxide mix (SPM) module, at least two cleaning elements, and a plurality of robots. The SPM module includes a sulfuric peroxide mix (SPM) cleaner having a first container to hold a sulfuric peroxide mix liquid and five to twenty first supports to hold five to twenty substrates in the liquid in the first container, and a rinsing station having a second container to hold a rinsing liquid and five to twenty second supports to hold five to twenty substrates in the liquid in the second container. Each of the at least two cleaning elements are configured to process a single substrate at a time. Examples of a cleaning element include a megasonic cleaner, a rotating brush cleaner, a buff pad cleaner, a jet spray cleaner, a chemical spin cleaner, a spin drier, and a marangoni drier.

Abstract: Cleaning chambers may include a substrate support having a substrate seating position. The cleaning chambers may include a plurality of fluid nozzles facing the substrate support. Each fluid nozzle of the plurality of fluid nozzles may define a fluid port characterized by a leading edge and a trailing edge. Each fluid nozzle of the plurality of fluid nozzles may be angled relative to the substrate seating position of the substrate support to produce an interior angle of greater than or about 90° at an intersection location across the substrate seating position for a fluid delivered from each fluid nozzle at the leading edge of the fluid port.

Abstract: Forming an integrated circuit, for example by first, concurrently forming a first front end of line (FEOL) layer having a first thickness and a surface contacting or facing a semiconductor substrate frontside and a second FEOL layer, having a second thickness and including a same material as the first FEOL layer and having a surface contacting or facing a semiconductor substrate backside, and second, processing the second FEOL layer to reduce the second thickness.

Abstract: Exemplary integrated cluster tools may include a factory interface including a first transfer robot. The tools may include a wet clean system coupled with the factory interface at a first side of the wet clean system. The tools may include a load lock chamber coupled with the wet clean system at a second side of the wet clean system opposite the first side of the wet clean system. The tools may include a first transfer chamber coupled with the load lock chamber. The first transfer chamber may include a second transfer robot. The tools may include a second transfer chamber coupled with the first transfer chamber. The second transfer chamber may include a third transfer robot. The tools may include a metal deposition chamber coupled with the transfer chamber.