Structures for a field-effect transistor and methods of forming a structure for a field-effect transistor. The structure includes a semiconductor substrate having a first trench, and a trench isolation region positioned in the first trench. The trench isolation region contains a dielectric material, the trench isolation region includes a second trench surrounded by the dielectric material, and the trench isolation region includes openings that penetrate through the dielectric material. A semiconductor layer is positioned in the second trench of the trench isolation region. The semiconductor layer contains a single-crystal semiconductor material.

An electronic device includes a substrate having a second conductivity type including a semiconductor surface layer with a buried layer (BL) having a first conductivity type. In the semiconductor surface layer is a first doped region (e.g., collector) and a second doped region (e.g., emitter) both having the first conductivity type, with a third doped region (e.g., a base) having the second conductivity type within the second doped region, wherein the first doped region extends below and lateral to the third doped region. At least one row of deep trench (DT) isolation islands are within the first doped region each including a dielectric liner extending along a trench sidewall from the semiconductor surface layer to the BL with an associated deep doped region extending from the semiconductor surface layer to the BL. The deep doped regions can merge forming a merged deep doped region that spans the DT islands.

Apparatus and methods are disclosed, including an apparatus that includes a number of tiers of a first semiconductor material, each tier including at least one access line of at least one memory cell and at least one source, channel and/or drain of at least one peripheral transistor, such as one used in an access line decoder circuit or a data line multiplexing circuit. The apparatus can also include a number of pillars of a second semiconductor material extending through the tiers of the first semiconductor material, each pillar including either a source, channel and/or drain of at least one of the memory cells, or a gate of at least one of the peripheral transistors. Methods of forming such apparatus are also described, along with other embodiments.

A method for forming layers with silicon is disclosed. The layers may be created by positioning a substrate within a processing chamber, heating the substrate to a first temperature between 300 and 500° C. and introducing a first precursor into the processing chamber to deposit a first layer. The substrate may be heated to a second temperature between 400 and 600° C.; and, a second precursor may be introduced into the processing chamber to deposit a second layer. The first and second precursor may comprise silicon atoms and the first precursor may have more silicon atoms per molecule than the second precursor.

Techniques for fabricating a memory device which has reduced neighboring word line interference, and a corresponding memory device. The memory device comprises a stack of alternating conductive and dielectric layers, where the conductive layers form word lines or control gates of memory cells. In one aspect, rounding off of the control gate layers due to inadvertent oxidation during fabrication is avoided. An amorphous silicon layer is deposited along the sidewall of the memory holes, adjacent to the control gate layers. Si.sub.3N.sub.4 is deposited along the amorphous silicon layer and oxidized in the memory hole to form SiO.sub.2. The amorphous silicon layer acts as an oxidation barrier for the sacrificial material of the control gate layers. The amorphous silicon layer is subsequently oxidized to also form SiO.sub.2. The two SiO.sub.2 layers together form a blocking oxide layer.

A multilayer composite structure and a method of preparing a multilayer composite structure are provided. The multilayer composite structure comprises a semiconductor handle substrate having a minimum bulk region resistivity of at least about 500 ohm-cm and an isolation region that impedes the transfer of charge carriers along the surface of the handle substrate and reduces parasitic coupling between RF devices.

A method for preparing silicon substrate having average crystallite size greater than or equal to 20 μm, including at least the steps of: (i) providing polycrystalline silicon substrate of which average grain size is less than or equal to 10 μm; (ii) subjecting substrate to overall homogeneous plastic deformation, at temperature of at least 1000° C.; (iii) subjecting substrate to localized plastic deformation in plurality of areas of substrate, called external stress areas, spacing between two consecutive areas being at least 20 μm, local deformation of substrate being strictly greater than overall deformation carried out in step (ii); step (iii) being able to be carried out subsequent to or simultaneous to step (ii); and (iv) subjecting substrate obtained in step (iii) to recrystallization heat treatment in solid phase, at temperature strictly greater than temperature used in step (ii), in order to obtain desired substrate.

Structures and methods for reducing process charging damages are disclosed. In one example, a silicon-on-insulator (SOI) structure is disclosed. The SOI structure includes: a substrate, a polysilicon region and an etch stop layer. The substrate includes: a handle layer, an insulation layer arranged over the handle layer, and a buried layer arranged over the insulation layer. The polysilicon region extends downward from an upper surface of the buried layer and terminates in the handle layer. The etch stop layer is located on the substrate. The etch stop layer is in contact with both the substrate and the polysilicon region.

A transistor comprises a top source/drain region, a bottom source/drain region, a channel region vertically between the top and bottom source/drain regions, and a gate operatively laterally-adjacent the channel region. At least one of the top source/drain region, the bottom source/drain region, and the channel region are crystalline. All crystal grains within the at least one of the top source/drain region, the bottom source/drain region, and the channel region have average crystal sizes within 0.064 μm.sup.3 of one another. Other embodiments, including methods, are disclosed.

A method of forming a crystalline silicon film includes forming a first amorphous silicon film on a substrate, forming a crystal nucleation film in which crystal nuclei of silicon are formed by performing a first annealing on the substrate having the first amorphous silicon film formed thereon, performing etching with an etching gas, forming a second amorphous silicon film on the crystal nuclei remaining after the etching, and forming a crystalline silicon film by performing a second annealing on the substrate after the forming of the second amorphous silicon film to grow the crystal nuclei.