Abstract: In an embodiment, a plasma source includes a first electrode, configured for transfer of one or more plasma source gases through first perforations therein; an insulator, disposed in contact with the first electrode about a periphery of the first electrode; and a second electrode, disposed with a periphery of the second electrode against the insulator such that the first and second electrodes and the insulator define a plasma generation cavity. The second electrode is configured for movement of plasma products from the plasma generation cavity therethrough toward a process chamber. A power supply provides electrical power across the first and second electrodes to ignite a plasma with the one or more plasma source gases in the plasma generation cavity to produce the plasma products. One of the first electrode, the second electrode and the insulator includes a port that provides an optical signal from the plasma.

Abstract: Methods may be performed to limit footing, pitch walking, and other alignment issues. The methods may include forming a treatment gas plasma within a processing region of a semiconductor processing chamber. The methods may further include directing effluents of the treatment gas plasma towards a semiconductor substrate within the processing region of the semiconductor processing chamber, and anisotropically modifying a surface of a first material on the semiconductor substrate with the effluents of the treatment gas plasma. The methods may also include passivating a surface of a second material on the semiconductor substrate with the effluents of the treatment gas plasma. The methods may further include forming a remote fluorine-containing plasma to produce fluorine-containing plasma effluents, and flowing the fluorine-containing plasma effluents to the processing region of the semiconductor processing chamber.

Abstract: Methods and apparatus to form fully self-aligned vias are described. First conductive lines are recessed in a first insulating layer on a substrate. A first metal film is formed in the recessed first conductive lines and pillars are formed from the first metal film. Some of the pillars are selectively removed and a second insulating layer is deposited around the remaining pillar. The remaining pillars are removed to form vias in the second insulating layer. A third insulating layer is deposited in the vias and an overburden is formed on the second insulating layer. Portions of the overburden are selectively etched from the second insulating layer to expose the second insulating layer and the filled vias and leaving portions of the third insulating layer on the second insulating layer. The third insulating layer is etched from the filled vias to form a via opening to the first conductive line.

Abstract: A first metallization layer comprising a set of first conductive lines that extend along a first direction on a first insulating layer on a substrate. A second insulating layer is on the first insulating layer. A second metallization layer comprises a set of second conductive lines on a third insulating layer and on the second insulating layer above the first metallization layer. The set of second conductive lines extend along a second direction that crosses the first direction at an angle. A via between the first metallization layer and the second metallization layer. The via is self-aligned along the second direction to one of the first conductive lines.

Abstract: Apparatuses and methods to provide a fully self-aligned via are described. Some embodiments of the disclosure provide an electronic device having a liner that is selectively removable when compared to conductive lines. The liner may be selectively removed by utilizing one or more of a base (e.g. sodium hydroxide) and hydrogen peroxide.

Abstract: Methods may be performed to limit footing, pitch walking, and other alignment issues. The methods may include forming a treatment gas plasma within a processing region of a semiconductor processing chamber. The methods may further include directing effluents of the treatment gas plasma towards a semiconductor substrate within the processing region of the semiconductor processing chamber, and anisotropically modifying a surface of a first material on the semiconductor substrate with the effluents of the treatment gas plasma. The methods may also include passivating a surface of a second material on the semiconductor substrate with the effluents of the treatment gas plasma. The methods may further include forming a remote fluorine-containing plasma to produce fluorine-containing plasma effluents, and flowing the fluorine-containing plasma effluents to the processing region of the semiconductor processing chamber.

Abstract: In an embodiment, a plasma source includes a first electrode, configured for transfer of one or more plasma source gases through first perforations therein; an insulator, disposed in contact with the first electrode about a periphery of the first electrode; and a second electrode, disposed with a periphery of the second electrode against the insulator such that the first and second electrodes and the insulator define a plasma generation cavity. The second electrode is configured for movement of plasma products from the plasma generation cavity therethrough toward a process chamber. A power supply provides electrical power across the first and second electrodes to ignite a plasma with the one or more plasma source gases in the plasma generation cavity to produce the plasma products. One of the first electrode, the second electrode and the insulator includes a port that provides an optical signal from the plasma.

Abstract: A first metallization layer comprising a set of first conductive lines that extend along a first direction on a first insulating layer on a substrate. A second insulating layer is on the first insulating layer. A second metallization layer comprises a set of second conductive lines on a third insulating layer and on the second insulating layer above the first metallization layer. The set of second conductive lines extend along a second direction that crosses the first direction at an angle. A via between the first metallization layer and the second metallization layer. The via is self-aligned along the second direction to one of the first conductive lines.

Abstract: Methods are described herein for etching metal films which are difficult to volatize. The methods include exposing a metal film to a chlorine-containing precursor (e.g. Cl2). Chlorine is then removed from the substrate processing region. A carbon-and-nitrogen-containing precursor (e.g. TMEDA) is delivered to the substrate processing region to form volatile metal complexes which desorb from the surface of the metal film. The methods presented remove metal while very slowly removing the other exposed materials. A thin metal oxide layer may be present on the surface of the metal layer, in which case a local plasma from hydrogen may be used to remove the oxygen or amorphize the near surface region, which has been found to increase the overall etch rate.

Abstract: In a 3D NAND device, the charge trap region of a memory cell is formed as a separate charge-trap “island.” As a result, the charge-trap region of one memory cell is electrically isolated from charge-trap regions in adjacent memory cells. The charge trap region of one memory cell is separated from the charge trap regions of adjacent memory cells by a dielectric structure, such as a silicon oxide film. Alternatively, the charge trap region of a memory cell is separated from the charge trap regions of adjacent memory cells by an air, gas, or vacuum gap.

Abstract: Exemplary methods for selective etching of semiconductor materials may include flowing a fluorine-containing precursor into a processing region of a semiconductor processing chamber. The methods may also include flowing a silicon-containing suppressant into the processing region of the semiconductor processing chamber. The methods may further include contacting a substrate with the fluorine-containing precursor and the silicon-containing suppressant. The substrate may include an exposed region of silicon nitride and an exposed region of silicon oxide. The methods may also include selectively etching the exposed region of silicon nitride to the exposed region of silicon oxide.

Abstract: Exemplary methods for selectively removing silicon (e.g. polysilicon) from a patterned substrate may include flowing a fluorine-containing precursor into a substrate processing chamber to form plasma effluents. The plasma effluents may remove silicon (e.g. polysilicon, amorphous silicon or single crystal silicon) at significantly higher etch rates compared to exposed silicon oxide, silicon nitride or other dielectrics on the substrate. The methods rely on the temperature of the substrate in combination with some conductivity of the surface to catalyze the etch reaction rather than relying on a gas phase source of energy such as a plasma.

Abstract: Methods may be performed to limit footing, pitch walking, and other alignment issues. The methods may include forming a treatment gas plasma within a processing region of a semiconductor processing chamber. The methods may further include directing effluents of the treatment gas plasma towards a semiconductor substrate within the processing region of the semiconductor processing chamber, and anisotropically modifying a surface of a first material on the semiconductor substrate with the effluents of the treatment gas plasma. The methods may also include passivating a surface of a second material on the semiconductor substrate with the effluents of the treatment gas plasma. The methods may further include forming a remote fluorine-containing plasma to produce fluorine-containing plasma effluents, and flowing the fluorine-containing plasma effluents to the processing region of the semiconductor processing chamber.

Abstract: Methods of etching a patterned substrate may include flowing an oxygen-containing precursor into a first remote plasma region fluidly coupled with a substrate processing region. The oxygen-containing precursor may be flowed into the region while forming a plasma in the first remote plasma region to produce oxygen-containing plasma effluents. The methods may also include flowing a fluorine-containing precursor into a second remote plasma region fluidly coupled with the substrate processing region while forming a plasma in the second remote plasma region to produce fluorine-containing plasma effluents. The methods may include flowing the oxygen-containing plasma effluents and fluorine-containing plasma effluents into the processing region, and using the effluents to etch a patterned substrate housed in the substrate processing region.

Abstract: A first metallization layer comprising a set of first conductive lines that extend along a first direction on a first insulating layer on a substrate. A second insulating layer is on the first insulating layer. A second metallization layer comprises a set of second conductive lines on a third insulating layer and on the second insulating layer above the first metallization layer. The set of second conductive lines extend along a second direction that crosses the first direction at an angle. A via between the first metallization layer and the second metallization layer. The via is self-aligned along the second direction to one of the first conductive lines.

Abstract: A first metallization layer comprising a set of first conductive lines that extend along a first direction on a first insulating layer on a substrate. A second insulating layer is on the first insulating layer. A second metallization layer comprises a set of second conductive lines on a third insulating layer and on the second insulating layer above the first metallization layer. The set of second conductive lines extend along a second direction that crosses the first direction at an angle. A via between the first metallization layer and the second metallization layer. The via is self-aligned along the second direction to one of the first conductive lines.

Abstract: Embodiments of the present technology may include a method of etching. The method may include mixing plasma effluents with a gas in a first section of a chamber to form a first mixture. The method may also include flowing the first mixture to a substrate in a second section of the chamber. The first section and the second section may include nickel plated material. The method may further include reacting the first mixture with the substrate to etch a first layer selectively over a second layer. In addition, the method may include forming a second mixture including products from reacting the first mixture with the substrate.

Abstract: Processing methods may be performed to form an airgap spacer on a semiconductor substrate. The methods may include forming a spacer structure including a first material and a second material different from the first material. The methods may include forming a source/drain structure. The source/drain structure may be offset from the second material of the spacer structure by at least one other material. The methods may also include etching the second material from the spacer structure to form the airgap. The source/drain structure may be unexposed to etchant materials during the etching.

Abstract: Processing methods may be performed to limit damage of features of a substrate, such as missing fin damage. The methods may include forming a plasma of an inert precursor within a processing region of a processing chamber. Effluents of the plasma of the inert precursor may be utilized to passivate an exposed region of an oxygen-containing material that extends about a feature formed on a semiconductor substrate. A plasma of a hydrogen-containing precursor may also be formed within the processing region. Effluents of the plasma of the hydrogen-containing precursor may be directed, with DC bias, towards an exposed silicon-containing material on the semiconductor substrate. The methods may also include anisotropically etching the exposed silicon-containing material with the plasma effluents of the hydrogen-containing precursor, where the plasma effluents of the hydrogen-containing precursor selectively etch silicon relative to silicon oxide.

Abstract: A first metallization layer comprising a set of first conductive lines that extend along a first direction on a first insulating layer on a substrate. A second insulating layer is on the first insulating layer. A second metallization layer comprises a set of second conductive lines on a third insulating layer and on the second insulating layer above the first metallization layer. The set of second conductive lines extend along a second direction that crosses the first direction at an angle. A via between the first metallization layer and the second metallization layer. The via is self-aligned along the second direction to one of the first conductive lines.