In the method for manufacturing a semiconductor structure, a film structure is formed on a substrate, a pattern transfer layer is formed on the film structure, a plurality of holes are defined on the pattern transfer layer, and the pattern transfer layer is flattened; the film structure is etched through the holes to form capacitor holes in the film structure.

The present disclosure relates to a method for forming a cavity that traverses a stack of layers including a bottom layer, a first portion of which locally presents an excess thickness, the method comprising a first step of non-selective etching and a second step of selective etching vertically in line with the first portion.

Methods of forming memory structures are discussed. Specifically, methods of forming 3D NAND devices are discussed. Some embodiments form memory structures with a metal nitride barrier layer, an α-tungsten layer, and a bulk metal material. The barrier layer comprises a TiXN or TaXN material, where X comprises a metal selected from one or more of aluminum (Al), silicon (Si), tungsten (W), lanthanum (La), yttrium (Yt), strontium (Sr), or magnesium (Mg).

A semiconductor structure and a forming method therefor are provided. The forming method includes: providing a base, a gate structure, a source/drain doped area, and a bottom dielectric layer; forming a source/drain interconnect layer running through the bottom dielectric layer on a top of the source/drain doped area; forming a top dielectric layer on the bottom dielectric layer; forming a gate contact running through the top dielectric layer on a top of the gate structure and a source/drain contact running through the top dielectric layer on a top of the source/drain interconnect layer; forming a sacrificial side wall layer on side walls of the gate contact and the source/drain contact; forming a gate plug filling the gate contact and a source/drain plug filling the source/drain contact; removing the sacrificial side wall layer to form a first gap; and forming a sealing layer sealing the first gap.

A preparation method of a semiconductor structure includes: a substrate including a groove structure is provided; a first isolation layer, a second isolation layer and a third isolation layer are sequentially formed on a bottom and sidewalls of the groove structure, where an upper surface of the first isolation layer is lower than an upper surface of the second isolation layer and an upper surface of the substrate to form a side trench; the third isolation layer is etched to enable an upper surface of the third isolation layer to be lower than the upper surface of the second isolation layer so that a top of the second isolation layer protrudes with respect to the first isolation layer and the third isolation layer to form a convex structure; and the second isolation layer is etched to remove the convex structure.

A method for multi-state pulsing to achieve a balance between bow control and mask selectivity is described. The method includes generating a primary radio frequency (RF) signal. The primary RF signal pulses among three states including a first state, a second state, and a third state. The method further includes generating a secondary RF signal. The secondary RF signal pulses among the three states. During the first state, the primary RF signal has a power level that is greater than a power level of the secondary RF signal. Also, during the second state, the secondary RF signal has a power level that is greater than a power level of the primary RF signal. During the third state, power levels of the primary and secondary RF signals are approximately equal.

A method for processing a workpiece, a plasma processing apparatus and a semiconductor device are provided. The method includes placing a workpiece including a spacer layer on a workpiece support in a chamber; selecting a composition modulation gas to modulate a volume ratio of carbon and fluorine to process the workpiece, the composition modulation gas includes one or more molecules, the volume ratio of carbon and fluorine is indicative of a distribution of carbon-based polymer deposited on the spacer layer; generating one or more species using one or more plasmas from a process gas to create a mixture, the process gas includes an etching gas and the composition modulation gas; and exposing the workpiece to the mixture to form a polymer layer on at least a portion of the spacer layer and to etch at least a portion of the spacer layer.

An embodiment of a method of integration of a non-volatile memory device into a logic MOS flow is described. Generally, the method includes: forming a pad dielectric layer of a MOS device above a first region of a substrate; forming a channel of the memory device from a thin film of semiconducting material overlying a surface above a second region of the substrate, the channel connecting a source and drain of the memory device; forming a patterned dielectric stack overlying the channel above the second region, the patterned dielectric stack comprising a tunnel layer, a charge-trapping layer, and a sacrificial top layer; simultaneously removing the sacrificial top layer from the second region of the substrate, and the pad dielectric layer from the first region of the substrate; and simultaneously forming a gate dielectric layer above the first region of the substrate and a blocking dielectric layer above the charge-trapping layer.

The present invention relates to the unexpected discovery of novel methods of preparing nanodevices and/or microdevices with predetermined patterns. In one aspect, the methods of the invention allow for engineering structures and films with continuous thickness equal to or less than 50 nm.

The present invention relates to the unexpected discovery of novel methods of preparing nanodevices and/or microdevices with predetermined patterns. In one aspect, the methods of the invention allow for engineering structures and films with continuous thickness equal to or less than 50 nm.