A method for manufacturing a semiconductor device includes forming a fin structure having a top face and a first side face and a second side face opposite to the first side face, forming a lower cover layer over the first and second side faces, forming an upper cover layer over the first and second side faces, the upper cover layer being spaced apart from the lower cover layer so that exposed regions of the first and second side faces are formed between the lower cover layer and the upper cover layer, and forming first and second semiconductor layers over the exposed regions of the first and second side faces, respectively.

A method for fabricating a metal-insulator-metal (MIM) capacitor includes the steps of: forming a capacitor bottom metal (CBM) layer on a material layer; forming a silicon layer on the CBM layer; forming a capacitor dielectric layer on the silicon layer; and forming a capacitor top metal (CTM) layer on the capacitor dielectric layer.

Methods of fabricating a memory device are provided. The methods may include forming a mask pattern including line-shaped portions that are parallel to each other and extend on a first region of a substrate. The mask pattern may extend on a second region of the substrate. The methods may also include forming word line regions in the first region using the mask pattern as a mask, forming word lines in the word line regions, respectively, and removing the mask pattern from the second region to expose the second region. The mask pattern may remain on the first region after removing the mask pattern from the second region. The methods may further include forming a channel epitaxial layer on the second region while using the mask pattern as a barrier to growth of the channel epitaxial layer on the first region.

To reduce a manufacturing cost of a semiconductor device in which a high breakdown voltage transistor and a trench capacitive element in which a part of an upper electrode is embedded in a trench formed in a main surface of a semiconductor substrate are mixed together. After an insulating film is formed over a main surface of a semiconductor substrate so as to cover a trench formed in the main surface of the semiconductor substrate, the insulating film is processed to form an upper electrode of a capacitive element, a gate insulating film which insulates the semiconductor substrate to be a lower electrode, and a gate insulting film of a high breakdown voltage transistor.

A method for manufacturing a semiconductor device includes forming first and second lower structures including selection elements on first and second chip regions of a substrate, respectively, forming first and second mold layers on the first and second lower structures, respectively, forming first and second support layers on the first and second mold layers, respectively, patterning the first support layer and the first mold layer to form first holes exposing the first lower structure, forming first lower electrodes in the first holes, forming a support pattern including at least one opening by selectively patterning the first support layer while leaving the second support layer, and removing the first mold layer through the opening. A top surface of the support pattern is disposed at a substantially same level as a top surface of the second support layer.

Structures and methods are provided for forming fin structures. A first fin structure is formed on a substrate. A shallow-trench-isolation structure is formed surrounding the first fin structure. At least part of the first fin structure is removed to form a cavity. A first material is formed on one or more side walls of the cavity. A second material is formed to fill the cavity, the second material being different from the first material. At least part of the STI structure is removed to form a second fin structure including the first material and the second material. At least part of the first material that surrounds the second material is removed to fabricate semiconductor devices.

A semiconductor device and a manufacturing method thereof are provided. The semiconductor device includes: a deep trench in a substrate; a sidewall insulating film on a side surface of the deep trench; an interlayer insulating film on the sidewall insulating film; and an air gap in the interlayer insulating film.

A method of manufacturing a semiconductor device, includes: forming an insulating film on a first surface of a semiconductor substrate; and forming a hydrogen supply film on a second surface facing the first surface of the semiconductor substrate, the hydrogen supply film containing one or more of silicon oxide, TEOS, BPSG, BSG, PSG, FSG, carbon-containing silicon oxide, silicon nitride, carbon-containing silicon nitride, and oxygen-containing silicon carbide.

A semiconductor memory device includes a semiconductor substrate having active areas and a trench isolation region between the active areas. The active areas extend along a first direction. Buried word lines extend along a second direction in the semiconductor substrate. Two of the buried word lines intersect with each of the active areas, separating each of the active areas into a digit line contact area and two cell contact areas. The second direction is not perpendicular to the first direction. A digit line contact is disposed on the digit line contact area. A storage node contact is disposed on each of the two cell contact areas. The digit line contact and the storage node contact are coplanar. At least one digit line extends along a third direction over a main surface of the semiconductor substrate. The at least one digit line is in direct contact with the digit line contact.

A metal-insulator-metal (MIM) capacitor design methodology and system substantially maximizes the benefits of including MIM capacitors in an integrated circuit design while substantially minimizing the negative impacts resulting from increased capacitance. A process analysis is performed on an integrated circuit design to determine a metal layer that is likely to be most adversely affected by the presence of MIM capacitor cells. The MIM capacitor cells are then designed to have specific sizes and orientations based on results of the process analysis, taking the most affected metal layer into consideration. Finally, the MIM capacitor cells are placed at selected locations on the die in an algorithmic fashion in order to satisfy a design target of maximizing coverage area while avoiding interference with signal paths and critical or sensitive components.