Thin tin oxide films are used as spacers in semiconductor device manufacturing. In one implementation, thin tin oxide film is conformally deposited onto a semiconductor substrate having an exposed layer of a first material (e.g., silicon oxide or silicon nitride) and a plurality of protruding features comprising a second material (e.g., silicon or carbon). For example, 10-100 nm thick tin oxide layer can be deposited using atomic layer deposition. Next, tin oxide film is removed from horizontal surfaces, without being completely removed from the sidewalls of the protruding features. Next, the material of protruding features is etched away, leaving tin oxide spacers on the substrate. This is followed by etching the unprotected portions of the first material, without removal of the spacers. Next, underlying layer is etched, and spacers are removed. Tin-containing particles can be removed from processing chambers by converting them to volatile tin hydride.

A device and method of spreading plasma which allows for plasma etching over a larger range of process chamber pressures. A plasma source, such as a linear inductive plasma source, may be choked to alter back pressure within the plasma source. The plasma may then be spread around a deflecting disc which spreads the plasma under a dome which then allows for very even plasma etch rates across the surface of a substrate. The apparatus may include a linear inductive plasma source above a plasma spreading portion which spreads plasma across a horizontally configured wafer or other substrate. The substrate support may include heating elements adapted to enhance the etching.

A method of processing a target object is provided. The target object includes a first protrusion portion, a second protrusion portion, and a groove portion provided on a main surface of the target object and defined by the first protrusion portion and the second protrusion portion and an inner surface of the groove portion is included in the main surface of the target object. The method comprises forming a protection film conformally on the main surface of the target object after the forming of the protection film conformally, repeatedly performing a plasma etching on a bottom portion of the groove portion of the target object and performing the forming of the protection film and the performing of the plasma etching N times (N is an integer equal to or larger than 2). The protection film is formed depending on a shape of the groove portion which has been changed by the plasma etching.

A device and method of spreading plasma which allows for plasma etching over a larger range of process chamber pressures. A plasma source, such as a linear inductive plasma source, may be choked to alter back pressure within the plasma source. The plasma may then be spread around a deflecting disc which spreads the plasma under a dome which then allows for very even plasma etch rates across the surface of a substrate. The apparatus may include a linear inductive plasma source above a plasma spreading portion which spreads plasma across a horizontally configured wafer or other substrate. The substrate support may include heating elements adapted to enhance the etching.

A plasma process apparatus is provided. The plasma processing apparatus includes a plasma chamber and a processing chamber. The processing chamber includes a substrate holder operable to support a substrate. The plasma processing apparatus further includes a separation grid separating the plasma chamber from the processing chamber. The separation grid includes a gas delivery system. The gas delivery system defines a channel, an inlet and a plurality of outlets in fluid communication with the inlet via the channel. The gas delivery system is configured to reduce non-uniformities associated with a treatment process performed on the substrate.

A substrate support in a semiconductor plasma processing apparatus, comprises multiple independently controllable thermal zones arranged in a scalable multiplexing layout, and electronics to independently control and power the thermal zones. A substrate support in which the substrate support is incorporated includes an electrostatic clamping electrode and a temperature controlled base plate. Methods for manufacturing the substrate support include bonding together ceramic or polymer sheets having thermal zones, power supply lines, power return lines and vias.

Thin tin oxide films are used as spacers in semiconductor device manufacturing. In one implementation, thin tin oxide film is conformally deposited onto a semiconductor substrate having an exposed layer of a first material (e.g., silicon oxide or silicon nitride) and a plurality of protruding features comprising a second material (e.g., silicon or carbon). For example, 10-100 nm thick tin oxide layer can be deposited using atomic layer deposition. Next, tin oxide film is removed from horizontal surfaces, without being completely removed from the sidewalls of the protruding features. Next, the material of protruding features is etched away, leaving tin oxide spacers on the substrate. This is followed by etching the unprotected portions of the first material, without removal of the spacers. Next, underlying layer is etched, and spacers are removed. Tin-containing particles can be removed from processing chambers by converting them to volatile tin hydride.

In an embodiment, a method includes: receiving, within a processing chamber, a wafer with a photoresist mask above a metal layer, wherein the processing chamber is connected to a gas source; applying an etchant configured to etch the metal layer in accordance with the photoresist mask within the processing chamber; and applying gas from the gas source to perform plasma ashing in the processing chamber.

A substrate process apparatus includes a chamber body providing a process space and a chamber lid coupled to the chamber body, the chamber lid includes a focus adapter providing a diffusion space of which width increases in a direction approaching a bottom of the focus adapter, a lid body surrounding the focus adapter, and a coupling adapter supporting the focus adapter, the lid body provides a coupling through hole recessed downwardly from an upper surface of the lid body, the coupling adapter provides a coupling recess recessed downwardly from an upper surface of the coupling adapter, and the coupling recess is spaced apart outwardly from the diffusion space and is located below the coupling through hole.

A system for plasma etching or ashing a coating on a substrate includes a plasma chamber, a second electrode, a plasma source coupled to the plasma chamber, a substrate including a coating, and a plasma mask including at least one aperture. The plasma chamber includes a first electrode. The plasma mask is configured to cover the substrate while exposing selected surfaces of the substrate and coating through the at least one aperture. The first electrode and the second electrode are configured to initiate and maintain a plasma within the plasma chamber. The plasma source includes a gas.