Abstract: Exemplary methods of semiconductor processing may include providing a silicon-containing precursor and an oxygen-containing precursor to a processing region of a semiconductor processing chamber. A substrate may be disposed within the processing region of the semiconductor processing chamber. The methods may include providing a carbon-containing precursor to the processing region of the semiconductor processing chamber. The carbon-containing precursor may be characterized by a carbon-carbon double bond or a carbon-carbon triple bond. The methods may include thermally reacting the silicon-containing precursor, the oxygen-containing precursor, and the carbon-containing precursor at a temperature below about 650° C. The methods may include forming a silicon-and-oxygen-and-carbon-containing layer on the substrate.

Abstract: A substrate processing method includes creating a mask on a top surface of a workpiece. A first portion of a gap fill material is overlaid by the mask and a second portion of the gap fill material is exposed through an opening in the mask. The method further includes exposing the workpiece to a plasma. The method further includes performing a first etching of the first portion of the gap fill material to create a first cavity while the second portion of the gap fill material remains in place, depositing a first metal-containing substance in the first cavity, performing a second etching of the second portion of the gap fill material to create a second cavity while the first metal-containing substance remains in place, and depositing a second metal-containing substance in the second cavity.

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: Examples of the present technology include semiconductor processing methods to form diffusion barriers for germanium in a semiconductor structure. The methods may include forming a semiconductor layer stack from pairs of Si-and-SiGe layers. The Si-and-SiGe layer pairs may be formed by forming a silicon layer, and then forming the germanium barrier layer of the silicon layer. In some embodiments, the germanium-barrier layer may be less than or about 20 ?. A silicon-germanium layer may be formed on the germanium-barrier layer to complete the formation of the Si-and-SiGe layer pair. In some embodiments, the silicon layer may be an amorphous silicon layer, and the SiGe layer may be characterized by greater than or about 5 atom % germanium. Examples of the present technology also include semiconductor structures that include a silicon-germanium layer, a germanium-barrier layer, and a silicon layer.

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: Memory devices and methods of manufacturing memory devices are provided. Described are devices and methods where 3D pitch multiplication decouples high aspect ratio etch width from cell width, creating small cell active area pitch to allow for small DRAM die size.

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: Hydrogen free (low-H) silicon dioxide layers are disclosed. Some embodiments provide methods for forming low-H layers using hydrogen-free silicon precursors and hydrogen-free oxygen sources. Some embodiments provide methods for tuning the stress profile of low-H silicon dioxide films. Further, some embodiments of the disclosure provide oxide-nitride stacks which exhibit reduced stack bow after anneal.

Abstract: Memory devices incorporating bridged word lines are described. The memory devices include a plurality of active regions spaced along a first direction, a second direction and a third direction. A plurality of conductive layers is arranged so that at least one conductive layer is adjacent to at least one side of each of the active regions along the third direction. A conductive bridge extends along the second direction to connect each of the conductive layers to one or more adjacent conductive layer. Some embodiments include an integrated etch stop layer. Methods of forming stacked memory devices are also described.

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: 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: 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 are described herein for etching tantalum-containing films with various potential additives while still retaining other desirable patterned substrate portions. The methods include exposing a tantalum-containing film to a chlorine-containing precursor (e.g. Cl2) with a concurrent plasma. The plasma-excited chlorine-containing precursor selectively etches the tantalum-containing film and other industrially-desirable additives. Chlorine is then removed from the substrate processing region. A hydrogen-containing precursor (e.g. H2) is delivered to the substrate processing region (also with plasma excitation) to produce a relatively even and residue-free tantalum-containing surface. The methods presented remove tantalum while retaining materials elsewhere on the patterned substrate.

Abstract: A method of conditioning internal surfaces of a plasma source includes flowing first source gases into a plasma generation cavity of the plasma source that is enclosed at least in part by the internal surfaces. Upon transmitting power into the plasma generation cavity, the first source gases ignite to form a first plasma, producing first plasma products, portions of which adhere to the internal surfaces. The method further includes flowing the first plasma products out of the plasma generation cavity toward a process chamber where a workpiece is processed by the first plasma products, flowing second source gases into the plasma generation cavity. Upon transmitting power into the plasma generation cavity, the second source gases ignite to form a second plasma, producing second plasma products that at least partially remove the portions of the first plasma products from the internal surfaces.

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: Embodiments of the present disclosure provide methods for forming features in a film stack. The film stack may be utilized to form stair-like structures with accurate profiles control in manufacturing three dimensional (3D) stacking of semiconductor chips. In one example, a method includes exposing a substrate having a multi-material layer formed thereon to radicals of a remote plasma to form one or more features through the multi-material layer, the one or more features exposing a portion of a top surface of the substrate, and the multi-material layer comprising alternating layers of a first layer and a second layer, wherein the remote plasma is formed from an etching gas mixture comprising a fluorine-containing chemistry, and wherein the process chamber is maintained at a pressure of about 2 Torr to about 20 Torr and a temperature of about ?100° C. to about 100° C.

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 and apparatus to form fully self-aligned vias are described. A seed gapfill layer is formed on a recessed first insulating layers positioned between first conductive lines. Pillars are formed from the seed gapfill layer and a second insulating layer is deposited in the gaps between pillars. The pillars are removed and a third insulating layer is deposited in the gaps in the second insulating layer to form an overburden of third insulating layer. A portion of the overburden of the third insulating layer is removed to expose the first conductive lines and form vias.

Abstract: A method of conditioning internal surfaces of a plasma source includes flowing first source gases into a plasma generation cavity of the plasma source that is enclosed at least in part by the internal surfaces. Upon transmitting power into the plasma generation cavity, the first source gases ignite to form a first plasma, producing first plasma products, portions of which adhere to the internal surfaces. The method further includes flowing the first plasma products out of the plasma generation cavity toward a process chamber where a workpiece is processed by the first plasma products, flowing second source gases into the plasma generation cavity. Upon transmitting power into the plasma generation cavity, the second source gases ignite to form a second plasma, producing second plasma products that at least partially remove the portions of the first plasma products from the internal surfaces.

Abstract: Methods and apparatus to form fully self-aligned vias are described. Portions of first conductive lines are recessed in a first insulating layer on a substrate. A first metal film is formed in the recessed portions of the first conductive lines and pillars are formed from the first metal film. A second insulating layer is deposited around the pillars. The 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.