Some embodiments include an integrated structure having vertically-stacked conductive levels. Upper conductive levels are memory cell levels, and a lower conductive level is a select device level. Conductively-doped semiconductor material is under the select device level. Channel material extends along the memory cell levels and the select device level, and extends into the conductively-doped semiconductor material. A region of the channel material that extends into the conductively-doped semiconductor material is a lower region of the channel material and has a vertical sidewall. Tunneling material, charge-storage material and charge-blocking material extend along the channel material and are between the channel material and the conductive levels. The tunneling material, charge-storage material and charge-blocking material are not along at least a portion of the vertical sidewall of the lower region of the channel material, and the conductively-doped semiconductor material is directly against such portion. Some embodiments include methods of forming integrated structures.

A semiconductor device structure includes a hybrid substrate having a semiconductor-on-insulator (SOI) region that includes an active semiconductor layer, a substrate material and a buried insulating material interposed between the active semiconductor layer and the substrate material, and a bulk semiconductor region that includes the substrate material. An insulating structure is positioned in the hybrid substrate, wherein the insulating structure separates the bulk region from the SOI region, and a gate electrode is positioned above the substrate material in the bulk region, wherein the insulating structure is in contact with two opposing sidewalls of the gate electrode.

A fuse memory comprising a discharge circuit is provided. The fuse memory includes a fuse cell array comprising fuse cells connected to read word lines, programs word lines, and bit lines arranged in rows and columns; and at least one discharge circuit arranged in each of the rows. The discharge circuit discharges a voltage level of a program word line of the fuse cells selected in a read mode to a ground voltage.

A method of exchanging or transforming end groups in and/or improving the ferroelectric properties of a PVDF-TrFE co-polymer is disclosed. A bulky or chemically dissimilar end group, such as an iodine, sulfate, aldehyde or carboxylic acid end group, may be transformed to a hydrogen, fluorine or chlorine atom. A method of making a PVDF-TrFE co-polymer is disclosed, including polymerizing a mixture of VDF and TrFE using an initiator, and transforming a bulky or chemically dissimilar end group to a hydrogen, fluorine or chlorine atom. A PVDF-TrFE co-polymer or other fluorinated alkene polymer is also disclosed. The co-polymer may be used as a ferroelectric, electromechanical, piezoelectric or dielectric material in an electronic device.

A semiconductor device includes an SOI substrate having a base substrate material, an active semiconductor layer positioned above the base substrate material and a buried insulating material layer positioned between the base substrate material and the active semiconductor layer. A gate structure is positioned above the active semiconductor layer and a back gate region is positioned in the base substrate material below the gate structure and below the buried insulating material layer. An isolation region electrically insulates the back gate region from the surrounding base substrate material, wherein the isolation region includes a plurality of implanted well regions that laterally contact and laterally enclose the back gate region and an implanted isolation layer that is formed below the back gate region.

A fuse structure includes a fusing line including a first portion, a second portion, and a central portion between the first portion and the second portion; and a dummy fuse neighboring the fusing line, the dummy fuse may include: a first air dummy fuse including a plurality of first air gaps extending in a first direction parallel to the fusing line; and a second air dummy fuse including a second air gap extending in a second direction crossing the fusing line.

An IC includes first and second designs of experiments (DOES), each comprised of at least two fill cells. The fill cells contain structures configured to obtain in-line data via non-contact electrical measurements (NCEM). The first DOE contains fill cells configured to enable non-contact (NC) detection of chamfer shorts, and the second DOE contains fill cells configured to enable NC detection of corner shorts.

Disclosed is a method of manufacturing a semiconductor device, including: forming a stacked structure including first material layers and second material layers alternately stacked on each other; forming a pillar passing through the stacked structure, the pillar including a protruding portion protruding above an uppermost surface of the stacked structure; forming a conductive layer surrounding the protruding portion of the pillar; and forming a conductive pattern in contact with the protruding portion of the pillar by oxidizing a surface of the conductive layer.

A method for manufacturing a memory device includes forming trenches in a substrate to define an active region, filling an insulation material in the trenches, treating at least one portion of the insulation material, removing an upper portion of the insulation material from the trenches, so as to expose upper portions of side surfaces of the active region and to convert remaining portions of the insulation material in the trenches to shallow trench isolation (STI) disposed on opposite sides of the active region, forming a lower oxide layer, a middle charge trapping layer, and an upper oxide layer which cover the exposed upper portions of the side surfaces of the active region, an upper surface of the active region between the side surfaces of the active region, and the STI, and forming a gate layer on the upper oxide layer.

Methods of forming 3-D ICs with integrated passive devices (IPDs) include stacking separately prefabricated substrates. An active device (AD) substrate has contacts on its upper portion. A ground plane is located between the AD substrate and an IPD substrate. The ground plane provides superior IPD to AD cross-talk attenuation.