A substrate processing method includes: holding a substrate having a processing target surface and an opposite surface which is opposite to the processing target surface; preheating a center portion of the opposite surface of the substrate; after the preheating, ejecting a sulfuric acid hydrogen peroxide mixture (SPM) to a peripheral edge portion of the processing target surface of the substrate; and after the ejecting, moving an ejection position of the SPM from the peripheral edge portion of the processing target surface to a center portion of the substrate.

An integrated circuit structure includes a semiconductor substrate, insulation regions extending into the semiconductor substrate, with the insulation regions including first top surfaces and second top surfaces lower than the first top surfaces, a semiconductor fin over the first top surfaces of the insulation regions, a gate stack on a top surface and sidewalls of the semiconductor fin, and a source/drain region on a side of the gate stack. The source/drain region includes a first portion having opposite sidewalls that are substantially parallel to each other, with the first portion being lower than the first top surfaces and higher than the second top surfaces of the insulation regions, and a second portion over the first portion, with the second portion being wider than the first portion.

An intermediate raw material according to the present invention includes a charge control agent having a critical packing parameter of 0.6 or more and a dispersing medium and a pH of the intermediate raw material is less than 7.

A method for manufacturing a semiconductor device includes forming a plurality of first semiconductor layers alternately stacked with a plurality of second semiconductor layers on a semiconductor substrate, and laterally recessing the plurality of first semiconductor layers with respect to the plurality of second semiconductor layers to form a plurality of vacant areas on lateral sides of the plurality of first semiconductor layers. In the method, a plurality of first inner spacers are formed on the lateral sides of the plurality of first semiconductor layers in respective ones of the plurality of vacant areas, and a plurality of second inner spacers are formed on sides of the plurality of first inner spacers in the respective ones of the plurality of vacant areas. The method also includes laterally recessing the plurality of second semiconductor layers, and growing a plurality of source/drain regions from the plurality of second semiconductor layers.

Aspects of this disclosure relate to selective removal of material of a layer, such as a carbon-containing layer. The layer can be over a patterned structure of two different materials. Treating the layer to cause the removal agent to be catalytically activated by a first area of the patterned structure to remove material of the organic material over the first area at a greater rate than over a second area of the patterned structure having a different composition from the first area.

A semiconductor component includes a substrate having an opening. The semiconductor component further includes a first dielectric liner in the opening, wherein the first dielectric liner having a thickness T.sub.1 at a first end of the opening, and a thickness T.sub.2 at a second end of the opening, and R.sub.1 is a ratio of T.sub.1 to T.sub.2. The semiconductor component further includes a second dielectric liner over the first dielectric liner, wherein the second dielectric liner having a thickness T.sub.3 at the first end of the opening, a thickness T.sub.4 at the second end of the opening, R.sub.2 is a ratio of T.sub.3 to T.sub.4, and R.sub.1 is greater than R.sub.2.

The present invention relates to a method for manufacturing a sample for thin film property measurement and analysis, and a sample manufactured thereby and, more specifically, to: a method for manufacturing a sample capable of measuring or analyzing various properties in one sample; and a sample manufactured thereby.

A method includes forming a fin structure on the substrate, wherein the fin structure includes a first fin active region; a second fin active region; and an isolation feature separating the first and second fin active regions; forming a first gate stack on the first fin active region and a second gate stack on the second fin active region; performing a first recessing process to a first source/drain region of the first fin active region by a first dry etch; performing a first epitaxial growth to form a first source/drain feature on the first source/drain region; performing a fin sidewall pull back (FSWPB) process to remove a dielectric layer on the second fin active region; and performing a second epitaxial growth to form a second source/drain feature on a second source/drain region of the second fin active region.

A method of fabricating a memory device includes forming an oxide layer on a semiconductor substrate, and forming an isolation structure in the semiconductor substrate and the oxide layer to define an active area. The method also includes forming a word line and a bit line in the semiconductor substrate, wherein the bit line is above the word line. The method further includes removing the oxide layer to form a recess between the isolation structure and the bit line, and forming a storage node contact in the recess. In addition, from a top view, the storage node contact of the memory device overlaps a corresponding portion of the active area.

A system and method for thinning an integrated circuit (IC) wafer. The system includes a support structure to hold the IC wafer and a mechanism to operate on the IC wafer. The support structure includes one or more inductive coils configured to transmit a power signal to the IC wafer and receive a feedback signal from the IC wafer. The system further includes a process controller to control the operation based at least in part on the feedback signal received from the IC wafer.