A substrate and a delamination film are separated by a physical means, or a mechanical means in a state where a metal film formed over a substrate, and a delamination layer comprising an oxide film including the metal and a film comprising silicon, which is formed over the metal film, are provided. Specifically, a TFT obtained by forming an oxide layer including the metal over a metal film; crystallizing the oxide layer by heat treatment; and performing delamination in a layer of the oxide layer or at both of the interface of the oxide layer is formed.

Some embodiments include a method of providing an electronic device. The method can comprise: providing a first device substrate; providing one or more first active sections over a second side of the first device substrate at a first device portion of the first device substrate; and after providing the first active section(s) over the second side of the first device substrate at the first device portion, folding a first perimeter portion of the first device substrate toward the first device portion at a first side of the first device substrate so that a first edge portion remains to at least partially frame the first device portion. The first edge portion can comprise a first edge portion width dimension smaller than a first smallest cross dimension of one or more pixel(s) of one or more semiconductor device(s) of the first active section(s). Other embodiments of related methods and devices are also disclosed.

To provide a semiconductor device with excellent electrical characteristics or a semiconductor device with stable electrical characteristics. A semiconductor device includes a first transistor, a second transistor, a first insulator, a second insulator, a first wiring, and a first plug. The first transistor includes silicon. The second transistor includes an oxide semiconductor. The first insulator is located over the first transistor. The second insulator is located over the first insulator. The second transistor is located over the second insulator. The first wiring is located over the second insulator and the first plug. The first transistor and the second transistor are electrically connected to each other through the first wiring and the first plug. The first wiring has low hydrogen permeability. The hydrogen permeability of the second insulator is lower than the hydrogen permeability of the first insulator.

New, distinct, and useful architectures for single-legged SOI-MOS were established and fabricated for the very first time. They incorporated into their architectures an innovative new configuration to wire the device Body to the Body-Tied-Source. This new configuration drastically increased the conductance between the Body and the Body-Tied-Source. This consequently allowed these devices to effectively support much higher operating biases. Same configuration also functioned on structures with very large peripheries. These gave proportional increase in this same conductivity, and for same area-efficiency, with the increase of their peripheries to accommodate higher currents. The functional model that governs this proportional scaling in these new architectures for single-legged SOI-MOS devices was established and is being claimed through this patent for the very first time. Through it, single-legged SOI-MOS devices will efficiently scale to area-efficient ultra large peripheries with minimal hits to their bandwidth.

A nanowire device includes a first component formed on a substrate and a second component disposed apart from the first component on the substrate. A nanowire is configured to connect the first component to the second component. An anchor pad is formed along a span of the nanowire and configured to support the nanowire along the span to prevent sagging.

The disclosure provides a manufacturing method and a structure thereof of a TFT backplane. In the manufacturing method of the TFT backplane, after a polysilicon layer (3) is formed by implanting a induced ion solid-phase crystallization into an amorphous silicon layer (3), patterning the polysilicon layer using a half-tone mask to form an island active layer (4), and at the same time, etching a upper layer portion (31) with more implanted induced ions located in the middle portion of the island active layer (4) to form a channel region, retaining the upper layer portion (31) with more implanted induced ions located in two sides of the island active layer (4) to form a source/drain contact region, it not only reduces the number of masks, but also saves a process only for implanting doped ion into the source/drain contact region, thereby simplifying the process and reducing production cost.

A transistor that is formed using an oxide semiconductor film is provided. A transistor that is formed using an oxide semiconductor film with reduced oxygen vacancies is provided. A transistor having excellent electrical characteristics is provided. A semiconductor device includes a first insulating film, a first oxide semiconductor film, a gate insulating film, and a gate electrode. The first insulating film includes a first region and a second region. The first region is a region that transmits less oxygen than the second region does. The first oxide semiconductor film is provided at least over the second region.

Methods and structures for forming a localized, strained region of a substrate are described. Trenches may be formed at boundaries of a localized region of a substrate. An upper portion of sidewalls at the localized region may be covered with a covering layer, and a lower portion of the sidewalls at the localized region may not be covered. A converting material may be formed in contact with the lower portion of the localized region, and the substrate heated. The heating may introduce a chemical species from the converting material into the lower portion, which creates stress in the localized region. The methods may be used to form strained-channel finFETs.

A semiconductor device having an n channel MISFET formed on an SOI substrate including a support substrate, an insulating layer formed on the support substrate and a silicon layer formed on the insulating layer has the following structure. An impurity region for threshold adjustment is provided in the support substrate of a gate electrode so that the silicon layer contains carbon. The threshold value can be adjusted by the semiconductor region for threshold adjustment in this manner. Further, by providing the silicon layer containing carbon, even when the impurity of the semiconductor region for threshold adjustment is diffused to the silicon layer across the insulating layer, the impurity is inactivated by the carbon implanted into the silicon layer. As a result, the fluctuation of the transistor characteristics, for example, the fluctuation of the threshold voltage of the MISFET can be reduced.

To provide a transistor with favorable electrical characteristics. A semiconductor device includes a first insulator over a substrate; a first metal oxide over the first insulator; a second metal oxide over the first metal oxide; a first conductor and a second conductor over the second metal oxide; a third metal oxide over the second metal oxide, the first conductor, and the second conductor; a second insulator over the third metal oxide; and a third conductor over the second insulator. The second metal oxide includes a region in contact with a top surface of the first metal oxide and regions in contact with side surfaces of the first metal oxide. The second metal oxide includes channel formation regions.