In an embodiment, a method includes: forming a fin extending from a substrate; forming a first gate mask over the fin, the first gate mask having a first width; forming a second gate mask over the fin, the second gate mask having a second width, the second width being greater than the first width; depositing a first filling layer over the first gate mask and the second gate mask; depositing a second filling layer over the first filling layer; planarizing the second filling layer with a chemical mechanical polish (CMP) process, the CMP process being performed until the first filling layer is exposed; and planarizing the first filling layer and remaining portions of the second filling layer with an etch-back process, the etch-back process etching materials of the first filling layer, the second filling layer, the first gate mask, and the second gate mask at the same rate.

A semiconductor device includes a first fin, a second fin, a first gate electrode having a first portion that at least partially wraps around an upper portion of the first fin and a second portion that at least partially wraps around an upper portion of the second fin, a second gate electrode having a portion that at least partially wraps around the upper portion of the first fin, and a gate-cut feature having a first portion in the first gate electrode between the first and second portions of the first gate electrode. The gate-cut feature is at least partially filled with one or more dielectric materials. In a direction of a longitudinal axis of the first fin, the gate-cut feature has a second portion extending to a sidewall of the second gate electrode.

A semiconductor substrate having a through-silicon via with an air gap interposed between the through-silicon via and the semiconductor substrate is provided. An opening is formed partially through the semiconductor substrate. The opening is first lined with a first liner and then the opening is filled with a conductive material. A backside of the semiconductor substrate is thinned to expose the first liner, which is subsequently removed and a second liner formed with a low-k or extra low-k dielectric is formed in its place.

The present application relates to a method for manufacturing an electro-optical device, wherein a waveguide (3) is provided (S1), a planarization coat (7) overlapping at least a section of the waveguide (3) is fabricated (S2), the planarization coat (7) is provided with a spin-on-glass coating (9) (S3), at least in the region of the spin-on-glass coating (9), a preferably dry chemical etching treatment is carried out (S4), optionally, the steps of providing the planarization coat (7) with a spin-on-glass coating (9) and the etching treatment are repeated at least once (S5, S6), and an active element (10) is provided (S7) on or above the planarization coat (7) and above the waveguide (3).

The present disclosure provides a non-isothermal wet atomic layer etch (ALE) process for etching polycrystalline materials, such as metals, metal oxides and silicon-based materials, formed on a substrate. More specifically, the present disclosure provides various embodiments of methods that utilize thermal cycling in a wet ALE process to independently optimize the reaction temperatures utilized within individual processing steps of the wet ALE process. Like conventional wet ALE processes, the wet ALE process described herein is a cyclic process that includes multiple cycles of surface modification and dissolution steps. Unlike conventional wet ALE processes, however, the wet ALE process described herein is a non-isothermal process that performs the surface modification and dissolution steps at different temperatures. This allows independent optimization of the surface modification and dissolution reactions.

Methods for forming a 3D memory device are provided. A method includes the following operations. A stack structure is formed in a staircase region and an array region. A dielectric material layer is formed over the array region and the staircase region. An etch mask layer is coated over the dielectric material layer. The etch mask layer, on a first surface away from the dielectric material layer, is planarized. The dielectric material layer and a remaining portion of the etch mask layer are etched to form a dielectric layer over the staircase region and the array region.

A manufacturing method of a semiconductor structure includes at least the following steps. A patterned mask layer with a first opening is formed on a dielectric layer overlying a semiconductor substrate. A portion of the dielectric layer accessibly exposed by the first opening of the patterned mask layer is removed to form a second opening. A first protective film is formed on inner sidewalls of the dielectric layer and the patterned mask layer, where the second opening and the first protective film are formed at the same step. A second protective film is formed on the first protective film to form a protective structure covering the inner sidewalls. A portion of the semiconductor substrate accessibly exposed by the second opening is removed to form a via hole including an undercut underlying the protective structure. The via hole is trimmed and a through substrate via is formed in the via hole.

A semiconductor device structure and a method for forming a semiconductor device structure are provided. The semiconductor device structure includes multiple semiconductor nanostructures over a substrate and two epitaxial structures over the substrate. Each of the semiconductor nanostructures is between the epitaxial structures, and the epitaxial structures are p-type doped. The semiconductor device structure also includes a gate stack wrapping around the semiconductor nanostructures. The semiconductor device structure further includes a dielectric stressor structure between the gate stack and the substrate. The epitaxial structures extend exceeding a top surface of the dielectric stressor structure.

A method, for making a semiconductor device, includes forming a first fin over a substrate. The method includes forming a dummy gate stack on the first fin. The method includes forming a first gate spacer along a side of the dummy gate stack. The first gate spacer includes a first dielectric material. The method includes forming a second gate spacer along a side of the first gate spacer. The second gate spacer includes a semiconductor material. The method includes forming a source/drain region in the first fin adjacent the second gate spacer. The method includes removing at least a portion of the second gate spacer to form a void extending between the first gate spacer and the source/drain region.

In a method of manufacturing a semiconductor device, an underlying structure is formed over a substrate. A film is formed over the underlying structure. Surface topography of the film is measured and the surface topography is stored as topography data. A local etching is performed by using directional etching and scanning the substrate so that an entire surface of the film is subjected to the directional etching. A plasma beam intensity of the directional etching is adjusted according to the topography data.