A semiconductor device includes an insulating layer (IFL) on a semiconductor substrate (SUB), a conductive film (PL) on the insulating layer (IFL), an interlayer insulating film (IL) covering the conductive film (PL), a contact hole (CH1) in the interlayer insulating film (IL), the conductive film (PL) and the insulating layer (IFL), and a plug (PG1) embedded in the contact hole (CH1). A side surface of the interlayer insulating film (IL) is separated from a side surface of the conductive film (PL) to expose a part of an upper surface of the conductive film (PL), and a side surface of the insulating layer (IFL) is separated from the side surface of the conductive film (PL) to expose a part of a lower surface of the conductive film (PL). A distance (L1) from the lower surface of the conductive film (PL) to the bottom of the contact hole (CH1) is longer than a distance (L2) from the side surface of the conductive film (PL) to the side surface of the interlayer insulating film (IL).

A planarization method includes the following steps. A silicon layer is deposited on a substrate, and a top surface of the silicon layer includes a lower portion and a bump portion protruding upwards from the lower portion. An ion bombardment etching process is performed to the silicon layer for reducing a surface step height of the silicon layer. The top surface of the silicon layer is etched by the ion bombardment etching process to become a post-etching top surface, and a distance between a topmost portion of the post-etching top surface and a bottommost portion of the post-etching top surface in a vertical direction is less than a distance between a topmost portion of the bump portion and the lower portion in the vertical direction before the ion bombardment etching process. Subsequently, a chemical mechanical polishing process is performed to the post-etching top surface of the silicon layer.

Methods of electrostatically clamping a glass substrate to a platen are disclosed. In one embodiment, a conductive layer is applied to the glass substrate, wherein the conductive layer provides the requisite clamping force. The transistor is then fabricated on the glass substrate. The conductive layer may be transparent, such that the bottom surface of the transistor may be inspected. In another embodiment, a lower polysilicon layer and oxide layer are deposited on the glass substrate. The transistor is then fabricated above the oxide layer.

The present disclosure provides a method of manufacturing a semiconductor structure. A substrate is provided. A multi-layer structure is formed over the substrate, wherein the multi-layer structure includes a semiconductive material layer and an oxide layer over the semiconductive material layer. The oxide layer is patterned to form a first patterned layer. A second patterned layer is formed on the semiconductive material layer and alternately arranged with the first patterned layer. A first etching operation is performed on the substrate using a comprehensive pattern of the first patterned layer and the second patterned layer.

In a method for preparing silicon-on-insulator, the first etching stop layer, the second etching stop layer, and the device layer are formed bottom-up on the p-type monocrystalline silicon epitaxial substrate, where the first etching stop layer is made of intrinsic silicon, the second etching stop layer is made of germanium-silicon alloy, and the device layer is made of silicon. After oxidation, bonding, reinforcement, and grinding treatment, selective etching is performed. Through a first selective etching to p+/intrinsic silicon, the thickness deviation of the first etching stop layer on the second etching layer is controlled within 100 nm, and then through the second etching and the third etching, the thickness deviation and the surface roughness of the finally prepared silicon-on-insulator film can be optimized to less than 5 nm and less than 4 , respectively, so as to realize the flatness of the silicon-on-insulator film.

A method includes providing a semiconductor substrate and forming a fin protruding from the semiconductor substrate. The method includes forming a silicon-containing layer over the fin. The method further includes patterning the silicon-containing layer to form a gate structure over the fin, where patterning the silicon-containing layer is implemented using an etchant and a passivant that includes a silicon-containing gas and a nitrogen-containing gas.

A manufacturing method of a semiconductor structure is provided. The method includes following steps. A substrate is provided, and the substrate has a first array region, a second array region, and a periphery region. A first lower conductive layer is formed on the substrate, the first lower conductive layer continuously has a first portion in the first array region, a second portion in the second array region, and a third portion in the periphery region. The first portion of the first lower conductive layer and the second portion of the first lower conductive layer are removed. A second lower conductive layer is formed on the substrate. The second lower conductive and the first lower conductive layer comprise the same material such that the second lower conductive and the first lower conductive layer form a lower conductive layer collectively.

The present disclosure provides a semiconductor device structure and a method for preparing the semiconductor device structure. The semiconductor device structure includes a first conductive layer disposed over a semiconductor substrate; a first dielectric layer disposed over the first conductive layer; an energy-removable layer conformally deposited over the first dielectric layer in a pattern-dense region; a patterned mask disposed over the first dielectric layer and the energy-removable layer, wherein the patterned mask includes a first pattern disposed in the pattern-dense region, a second pattern disposed over a sidewall of the first pattern, and a third pattern disposed in a pattern-loose region; and a plurality of processed areas disposed on a top surface of the energy-removable layer and between two adjacent first patterns and also disposed on the first pattern. A second critical dimension of the second pattern is smaller than a first critical dimension of the first pattern.

A manufacture includes a polysilicon structure over a portion of a substrate. The manufacture further includes a spacer on a sidewall of the polysilicon structure, wherein the spacer has a concave corner region between an upper portion and a lower portion, the spacer has an outer sidewall and an inner sidewall, and the inner sidewall is between the outer sidewall and the polysilicon structure. The manufacture further includes a protective layer exposing a portion of the outer sidewall of the spacer above the concave corner region, wherein the protective layer covers an entirety of the lower portion of the spacer, and the protective layer directly contacts the substrate.