The present disclosure relates to a susceptor having a generally circular body having a face with a radially inward section and a radially outward section which includes a substrate supporting surface elevated relative to the radially inward section. A sidewall surrounds the substrate supporting surface which upon retention of a substrate on the radially outward section, the sidewall surrounds the substrate. The sidewall includes a plurality of humps which protrude from the top surface of the sidewall. Advantageously, the plurality of humps may aid in even thickness of deposition of material at the edge of the substrate.

According to one embodiment, film formation apparatus includes: a carrying unit that includes a rotation table which circulates and carries a workpiece; a film formation process unit which includes a target formed of a silicon material, and a plasma producer that produces plasma of a sputter gas introduced between the target and the rotation table, and which forms a silicon film on the workpiece by sputtering; and a hydrogenation process unit which includes a process gas introducing unit that introduces a process gas containing a hydrogen gas, and a plasma producer that produces plasma of the process gas, and which performs hydrogenation on the silicon film formed on the workpiece. The carrying unit carries the workpiece so as to alternately pass through the film formation process unit and through the hydrogenation process unit.

Methods and systems for forming films on substrates in semiconductor processes are disclosed. The method includes providing different materials each contained in separate ampoules. Material is flowed from each ampoule into a separate portion of a showerhead contained within a process chamber via a heated gas line. From the showerhead, each material is flowed on to a substrate that sits on the surface of a rotating pedestal. Controlling the mass flow rate out of the showerhead and the rotation rate of the pedestal helps result in films with desirable material domain sizes to be deposited on the substrate.

A film forming method includes: rotating a rotary table to revolve a substrate which is placed on the rotary table and has a recess in its surface; supplying a raw material gas to a first region on the rotary table; supplying an ammonia gas to a second region on the rotary table; forming a first SiN film in the recess by supplying the raw material gas to the first region and supplying the ammonia gas to the second region at a first flow rate, while the rotary table rotates at a first rotation speed; and forming a second SiN film in the recess such that the second SiN film is laminated on the first SiN film by supplying the raw material gas to the first region and supplying the ammonia gas to the second region at a second flow rate, while the rotary table rotates at a second rotation speed.

Embodiments of the present disclosure include methods and apparatuses utilized to reduce particle generation within a processing chamber. In one or more embodiments, a lid for a substrate processing chamber is provided and includes a cover member, a central opening, and a trench. An inner profile of the central opening contains a first section having a first diameter, a second section having a second diameter, and a third section having a third diameter. The second section is disposed between and connected to the first section and the third section. The first diameter gradually increases from the second section toward the surface of the cover member, the second diameter cylindrically extends from the first section to the third section, and the third diameter is less than the second diameter. The trench surrounds the central opening and is formed along a closed path in the surface of the cover member.

Embodiments of the present disclosure include methods and apparatuses utilized to reduce particle generation within a processing chamber. In one or more embodiments, a lid for a substrate processing chamber is provided and includes a cover member, a central opening, and a trench. An inner profile of the central opening contains a first section having a first diameter, a second section having a second diameter, and a third section having a third diameter. The second section is disposed between and connected to the first section and the third section. The first diameter gradually increases from the second section toward the surface of the cover member, the second diameter cylindrically extends from the first section to the third section, and the third diameter is less than the second diameter. The trench surrounds the central opening and is formed along a closed path in the surface of the cover member.

A plasma processing apparatus includes a stage for supporting a target object in a chamber defined by a chamber body. The stage includes a lower electrode, an electrostatic chuck provided on the lower electrode, heaters provided in the electrostatic chuck, and terminals electrically connected to the heaters. A conductor pipe electrically connects a high frequency power supply and the lower electrode and extends from the lower electrode to the outside of the chamber body. Power supply lines supply power from a heater controller to the heaters. Filters partially forming the power supply lines prevent the inflow of high frequency power from the heaters to the heater controller. The power supply lines include wirings which respectively connect the terminals and the filters and extend to the outside of the chamber body through an inner bore of the conductor pipe.

A film deposition method and a film deposition apparatus are provided. The film deposition method includes: putting a substrate into a furnace tube, the furnace tube including a first section for placing the substrate, the first section having an inlet for reaction gas; heating, within a first preset time, a first heating module from a first initial temperature to a first preset temperature, the first heating module surrounding the first section and being configured to heat the first section; maintaining, within a second preset time, the first heating module continuously at the first preset temperature; and within a third preset time, introducing the reaction gas into the furnace tube from the inlet, and heating the first heating module from the first preset temperature to a second preset temperature so as to form a target film on a surface of the substrate placed in the first section.

A non-planar chemical vapour deposition polycrystalline diamond body has a dome body having an apex and an outer periphery. The dome body has an average radius of curvature in a range of 4 mm to 25 mm and a maximum linear dimension at the outer periphery of the dome body of no more than 26 mm. The average radius of curvature is no less than 0.6 times the maximum linear dimension at the outer periphery. A method of fabricating the non-planar diamond body is also disclosed.

A wafer support table includes a ceramic base having a wafer placement surface and including an RF electrode and a heater electrode embedded, the RF electrode being closer to the wafer placement surface; a hole extending from a surface of the ceramic base opposite the wafer placement surface toward the RF electrode; and an RF rod through having a top end joined to the RF electrode or joined to a conductive member connected to the RF electrode, wherein the RF rod is a hybrid rod including a first rod member that is made of Ni and constitutes a portion of the RF rod from the top end to a predetermined position and a second rod member that is joined to the first rod member and constitutes a portion of the RF rod from the predetermined position to the base end and is made of a non-magnetic material.