Disclosed are approaches for forming semiconductor device cavities. One method may include providing a set of semiconductor structures defining an opening, wherein the opening has a first opening width along an upper portion of the opening and a second opening width along a lower portion of the opening, the first opening width being greater than the second opening width. The method may further include forming a blocking layer along the set of semiconductor structures by delivering a material at a non-zero angle of inclination relative to a normal extending perpendicular from a top surface of the set of semiconductor structures. The blocking layer may be formed along the upper portion of the opening without being formed along the lower portion of the opening, and wherein an opening through the blocking layer is present above the opening.

Disclosed are approaches for forming semiconductor device cavities. One method may include providing a set of semiconductor structures defining an opening, wherein the opening has a first opening width along an upper portion of the opening and a second opening width along a lower portion of the opening, the first opening width being greater than the second opening width. The method may further include forming a blocking layer along the set of semiconductor structures by delivering a material at a non-zero angle of inclination relative to a normal extending perpendicular from a top surface of the set of semiconductor structures. The blocking layer may be formed along the upper portion of the opening without being formed along the lower portion of the opening, and wherein an opening through the blocking layer is present above the opening.

An ion implantation system, ion source, and method are provided, where an ion source is configured to ionize an aluminum-based ion source material and to form an ion beam and a by-product including a non-conducting material. An etchant gas mixture has a predetermined concentration of fluorine and a noble gas that is in fluid communication with the ion source. The predetermined concentration of fluorine is associated with a predetermined health safety level, such as approximately a 20% maximum concentration of fluorine. The etchant gas mixture can have a co-gas with a concentration less than approximately 5% of argon. The aluminum-based ion source material can be a ceramic member, such as a repeller shaft, a shield, or other member within the ion source.

A system, method, and apparatus for heating and cooling a component in chamber enclosing a chamber volume. Vacuum and purge gas ports are in fluid communication with the chamber volume. A heater apparatus selectively heats the heated apparatus to a process temperature. A vacuum valve provides selective fluid communication between a vacuum source and the vacuum port. A purge gas valve provides selective fluid communication between a purge gas source for a purge gas and the purge gas port. A controller controls the heater apparatus, vacuum and purge gas valves and to selectively flow the purge gas to the chamber volume when an equipment-safe temperature is reached. When an operator-safe temperature is reached, access to the chamber volume through an access port by an operator is permitted.

Aspects of the present disclosure generally relate to oscillating a boundary layer of a flow of process gas in methods and systems for processing substrates. In one aspect, one or more of a pressure, a gas flow rate, and/or a height of a substrate are oscillated during processing. In one implementation, a method of processing a substrate includes conducting a processing operation on the substrate in an interior volume of a processing chamber. The conducting the processing operation on the substrate includes moving a flow of one or more process gases over a surface of the substrate. The method also includes oscillating a boundary layer of the flow of one or more process gases while the flow of one or more process gases moves over the surface of the substrate.

Aspects of the present disclosure generally relate to oscillating a boundary layer of a flow of process gas in methods and systems for processing substrates. In one aspect, one or more of a pressure, a gas flow rate, and/or a height of a substrate are oscillated during processing. In one implementation, a method of processing a substrate includes conducting a processing operation on the substrate in an interior volume of a processing chamber. The conducting the processing operation on the substrate includes moving a flow of one or more process gases over a surface of the substrate. The method also includes oscillating a boundary layer of the flow of one or more process gases while the flow of one or more process gases moves over the surface of the substrate.

An apparatus and method of processing a workpiece is disclosed, where a sacrificial capping layer is created on a top surface of a workpiece. That workpiece is then exposed to an ion implantation process, where select species are used to passivate the workpiece. While the implant process is ongoing, radicals and excited species etch the sacrificial capping layer. This reduces the amount of etching that the workpiece experiences. In certain embodiments, the thickness of the sacrificial capping layer is selected based on the total time used for the implant process and the etch rate. The total time used for the implant process may be a function of desired dose, bias voltage, plasma power and other parameters. In some embodiments, the sacrificial capping layer is applied prior to the implant process. In other embodiments, material is added to the sacrificial capping layer during the implant process.

An apparatus and method of processing a workpiece is disclosed, where a sacrificial capping layer is created on a top surface of a workpiece. That workpiece is then exposed to an ion implantation process, where select species are used to passivate the workpiece. While the implant process is ongoing, radicals and excited species etch the sacrificial capping layer. This reduces the amount of etching that the workpiece experiences. In certain embodiments, the thickness of the sacrificial capping layer is selected based on the total time used for the implant process and the etch rate. The total time used for the implant process may be a function of desired dose, bias voltage, plasma power and other parameters. In some embodiments, the sacrificial capping layer is applied prior to the implant process. In other embodiments, material is added to the sacrificial capping layer during the implant process.

A heated chuck for an ion implantation system selectively clamps a workpiece to a carrier plate having heaters to selectively heat a clamping surface. A gap between a base plate and carrier plate of the heated chuck contains a heat transfer media. A cooling fluid source is coupled to cooling channels in the base plate. A controller operates the heated chuck in a first mode and second mode. In the first mode, the controller does not activate the heaters and flows the cooling fluid through the cooling channel, where heat is transferred through the heat transfer media and to the cooling fluid. In the second mode, the controller activates the heaters and optionally purges the cooling fluid from the cooling channel or otherwise alters its cooling capacity. A gas can be selectively provided in the gap to further control heat transfer in the first and second modes.

A heated chuck for an ion implantation system selectively clamps a workpiece to a carrier plate having heaters to selectively heat a clamping surface. A gap between a base plate and carrier plate of the heated chuck contains a heat transfer media. A cooling fluid source is coupled to cooling channels in the base plate. A controller operates the heated chuck in a first mode and second mode. In the first mode, the controller does not activate the heaters and flows the cooling fluid through the cooling channel, where heat is transferred through the heat transfer media and to the cooling fluid. In the second mode, the controller activates the heaters and optionally purges the cooling fluid from the cooling channel or otherwise alters its cooling capacity. A gas can be selectively provided in the gap to further control heat transfer in the first and second modes.