A semiconductor structure that includes crystalline surfaces and amorphous hydrophilic surfaces is provided. The hydrophilic surfaces are treated with silane that includes a hydrophobic functional group, converting the hydrophilic surfaces to hydrophobic surfaces. Chemical vapor deposition or other suitable deposition methods are used to simultaneously deposit a material on both surfaces and due to the surface treatment, the deposited material exhibits superior adherence qualities on both surfaces. In one embodiment, the structure is an opening formed in a semiconductor substrate and bounded by at least one portion of a crystalline silicon surface and at least one portion of an amorphous silicon oxide structure.

Trenches (and processes for forming the trenches) are provided that reduce or prevent crystaline defects in selective epitaxial growth of type III-V or Germanium (Ge) material (e.g., a buffer material) from a top surface of a substrate material. The defects may result from collision of selective epitaxial sidewall growth with oxide trench sidewalls. Such trenches include (1) a trench having sloped sidewalls at an angle of between 40 degrees and 70 degrees (e.g., such as 55 degrees) with respect to a substrate surface; and/or (2) a combined trench having an upper trench over and surrounding the opening of a lower trench (e.g., the lower trench may have the sloped sidewalls, short vertical walls, or tall vertical walls). These trenches reduce or prevent defects in the epitaxial sidewall growth where the growth touches or grows against vertical sidewalls of a trench it is grown in.

A semiconductor structure includes a substrate, a first power device and a second power device in the substrate, at least one isolation feature between the first and second power device, and a trapping feature adjoining the at least one isolation feature in the substrate.

A semiconductor device includes a substrate, a plurality of memory cell arrays, and an air gap structure. The substrate includes a cell region, a peripheral circuit region, and a boundary region. The boundary region is between the cell region and the peripheral circuit region. The plurality of memory cell arrays are on the cell region. The air gap structure includes a trench formed in the boundary region of the substrate. The air gap structure defines an air gap.

The present disclosure provides an embodiment of a fin-like field-effect transistor (FinFET) device. The device includes a substrate having a first gate region, a first fin structure over the substrate in the first gate region. The first fin structure includes an upper semiconductor material member, a lower semiconductor material member, surrounded by an oxide feature and a liner wrapping around the oxide feature of the lower semiconductor material member, and extending upwards to wrap around a lower portion of the upper semiconductor material member. The device also includes a dielectric layer laterally proximate to an upper portion of the upper semiconductor material member. Therefore the upper semiconductor material member includes a middle portion that is neither laterally proximate to the dielectric layer nor wrapped by the liner.

A method for forming a semiconductor device comprises forming a first buffer layer with a first melting point on a substrate. A second buffer layer is formed on the first buffer layer. The second buffer layer has a second melting point that is greater than the first melting point. Annealing process is performed that increases a temperature of the first buffer layer such that the first buffer layer partially liquefies and causes a strain in the second buffer layer to be substantially reduced.

A single fin or a pair of co-integrated n- and p-type single crystal electronic device fins are epitaxially grown from a substrate surface at a bottom of one or a pair of trenches formed between shallow trench isolation (STI) regions. The fin or fins are patterned and the STI regions are etched to form a height of the fin or fins extending above etched top surfaces of the STI regions. The fin heights may be at least 1.5 times their width. The exposed sidewall surfaces and a top surface of each fin is epitaxially clad with one or more conformal epitaxial materials to form device layers on the fin. Prior to growing the fins, a blanket buffer epitaxial material may be grown from the substrate surface; and the fins grown in STI trenches formed above the blanket layer. Such formation of fins reduces defects from material interface lattice mismatches.

A manufacturing method of a semiconductor device according to a disclosed embodiment includes: implanting a first impurity into a first region of a semiconductor substrate, forming a semiconductor layer on the semiconductor substrate, forming a trench in the semiconductor layer and the semiconductor substrate, forming an isolation insulating film in the trench, implanting a second impurity into a second region of the semiconductor layer, forming a first gate insulating film and a first gate electrode in the first region, forming a second gate insulating film and a second gate electrode in the second region, forming a first source region and a first drain region at both sides of the first gate electrode, and forming a second source region and a second drain region at both sides of the second gate electrode.

A method of fabricating an integrated circuit (IC) includes etching a trench in a semiconductor substrate having an aspect ratio (AR) 5 and a trench depth 10 m. A dielectric liner is formed along the walls of the trench to form a dielectric lined trench. In-situ doped polysilicon is deposited into the trench to form a dielectric lined polysilicon filled trench having a doped polysilicon filler therein. The doped polysilicon filler after completion of fabricating the IC is essentially polysilicon void-free and has a 25 C. sheet resistance 100 ohms/sq. The method can include etching an opening at a bottom of the dielectric liner before depositing the polysilicon to provide ohmic contact to the semiconductor substrate.

A semiconductor device that includes a first plurality of fin structures in a first device region and a second plurality of fin structures in a second device region. The first plurality of fin structures includes adjacent fin structures separated by a lesser pitch than the adjacent fin structures in the second plurality of fin structures. At least one layer of dielectric material between adjacent fin structures, wherein a portion of the first plurality of fin structures extending above the at least one layer of dielectric material in the first device region is substantially equal to the portion of the second plurality of fin structures extending above the at least one layer of dielectric material in the second device region. Source and drain regions are present on opposing sides of a gate structure that is present on the fin structures.