Abstract: A method for forming a Field Effect Transistor (FET) within a strain effect semiconductor layer is disclosed, whereby the source and drain of the FET are formed only in the strain effect silicon layer. The FET may be formed as a gate electrode of a p-channel type field effect transistor, and a gate electrode of a n-channel type field effect transistor on the silicon layer which has the strain effect through a gate insulating film. The sources and drains of p- and n-type diffusion layers are then formed in the silicon layer having the strain effect, on both sides of the gate electrode.

Abstract: Embodiments of the present invention provide a method for forming an emitter region in a crystalline silicon substrate and passivating the surface thereof by depositing a doped amorphous silicon layer onto the crystalline silicon substrate and thermally annealing the crystalline silicon substrate while oxidizing the surface thereof. In one embodiment, the deposited film is completely converted to oxide. In another embodiment, the doped amorphous silicon layer deposited onto the crystalline silicon substrate is converted into crystalline silicon having the same grain structure and crystal orientation as the underlying crystalline silicon substrate upon which the amorphous silicon was initially deposited during emitter formation. In one embodiment, at least a portion of the converted crystalline silicon is further converted into silicon dioxide during the emitter surface passivation.

Abstract: In accordance with the present invention, a novel method to fabricate topological capacitors is provided. The fabrication method of the instant invention is based upon a reversed surface topology utilizing deep reactive ion etching to establish conductive capacitive elements and non-conductive capacitive element groups.

Abstract: The method of fabricating semiconducting nanowires having a desired wire diameter includes providing pre-fabricated semiconducting nanowires, at least one pre-fabricated nanowire having a wire diameter larger than the desired wire diameter (d); and reducing the wire diameter of the at least one pre-fabricated nanowire by etching. The etching is induced by light which is absorbed by the at least one pre-fabricated nanowire. The spectrum of the light is chosen such that the absorption of the at least one pre-fabricated nanowire is significantly reduced when the at least one pre-fabricated nanowire reaches the desired wire diameter.

Abstract: A method of forming a flash memory device can include forming a tunneling oxide film on a semiconductor substrate, forming a charge storing layer on the tunneling oxide film, forming a first blocking oxide film on the charge storing layer at a first temperature, forming a second blocking oxide film on the first blocking oxide film at a second temperature higher than the first temperature, and forming a gate electrode on the second blocking oxide film.

Abstract: A method of forming minute patterns in a semiconductor device, and more particularly, a method of forming minute patterns in a semiconductor device having an even number of insert patterns between basic patterns by double patterning including insert patterns between a first basic pattern and a second basic pattern which are transversely separated from each other on a semiconductor substrate, wherein a first insert pattern and a second insert pattern are alternately repeated to form the insert patterns, the method includes the operation of performing a partial etching toward the second insert pattern adjacent to the second basic pattern, or the operation of forming a shielding layer pattern, thereby forming the even number of insert patterns.

Abstract: There is provided a method of forming a pattern on a group III nitride semiconductor substrate. A method of forming a pattern on a group III nitride semiconductor substrate according to an aspect of the invention may include: irradiating a laser beam onto at least one first region for preventing etching in a group III nitride semiconductor substrate; and etching at least one second region exclusive of the first region using the first region irradiated with the laser beam as a mask.

Abstract: After a groove is formed in an insulating layer formed on a semiconductor substrate, a barrier metal layer is formed on the insulating layer by an ALD process so as to cover the side walls and bottom of the groove, and an impurity layer is formed in or on the surface of the barrier metal layer by an ion implantation process or by an ALD process. Thereafter, the barrier metal layer and the impurity layer are alloyed, and then an inlaid interconnect layer, which is composed of a Cu seed layer and a Cu plating layer, is formed in the groove. Then, an impurity element in the alloyed barrier metal layer is thermally diffused into the inlaid interconnect layer.

Abstract: Insulating films (13, 14) are formed on the surface of a semiconductor wafer (30) on the side on which a plurality of devices are formed. Then, conductor layers (15, 16) are formed to cover opening portions from which electrode pads (12) of each device are exposed. Furthermore, a resist layer (R2) is formed to have opening portions from which terminal formation portions of the conductor layer are exposed, and metal posts (17) are formed on the terminal formation portions of the conductor layer (16) using the resist layer (R2) as a mask. Then, thinning of the semiconductor wafer (30) is performed to a predetermined thickness by grinding the back surface thereof. Thereafter, the resist layer (R2) is removed; an unnecessary portion (15) of the conductor layer is further removed; sealing with sealing resin is performed with the top portions of the metal posts (17) being exposed; metal bumps are bonded to the top portions of the metal posts (17); and the semiconductor wafer is divided into each device.

Abstract: A method of forming a ferroelectric layer is provided. A metal-organic source gas is provided into a chamber into which an oxidation gas is provided for a first time period to form ferroelectric grains on a substrate. A ferroelectric layer is formed by performing at least twice a step of providing a metal-organic source gas into the chamber during the first time period using a pulse method to grow the ferroelectric grains.

Abstract: A method for manufacturing a pixel structure is provided. A gate and a gate insulating layer are sequentially formed on a substrate. A semiconductor layer and a second metal layer are sequentially formed on the gate insulating layer. The semiconductor layer and the second metal layer are patterned to form a channel layer, a source and a drain by using a patterned photoresist layer formed thereon, wherein the source and drain are disposed on a portion of the channel layer. The gate, channel, source and drain form a thin film transistor. A passivation layer is formed on the patterned photoresist layer, the gate insulating layer and the thin film transistor. Then, the patterned photoresist layer is removed, such that the passivation layer thereon is removed simultaneously to form a patterned passivation layer and the drain is exposed. A pixel electrode is formed on the patterned passivation layer and the drain.

Abstract: The present invention provides a method of manufacturing a metal silicide electrode (100) for a semiconductor device (110). The method comprises depositing by physical vapor deposition, germanium atoms (120) and transition metal atoms (130) to form a metal-germanium alloy layer (140) on a semiconductor substrate (150). The metal-germanium alloy layer and the semiconductor substrate are reacted to form a metal silicide electrode. Other aspects of the present invention include a method of manufacturing an integrated circuit (400).

Abstract: A semiconductor device includes a memory section formed at a semiconductor substrate and including a first transistor having an ONO film that can store charges between the semiconductor substrate and a memory electrode and a first STI region for isolating the first transistor, and a CMOS section formed at the semiconductor substrate and including a second transistor having a CMOS electrode and a gate dielectric and a second STI region for isolating the second transistor. The height of the top surface of the first STI region is set equal to or smaller than the height of the top surface of the second STI region.

Abstract: In a semiconductor manufacturing method, a metal film is formed on a substrate and heat treated. The relationship between substrate warping and the heat treatment temperature during silicide formation is acquired (S1). A silicide film is formed by forming a metal film on a substrate and heat treating, including substrate measurement during heat treatment (S2). The relationship between substrate warping at heat treatment temperature is determined from the relationship between the warping of the substrate and the temperature for heat treatment and the temperature for heat treatment carried out on the substrate when the warping of the substrate is measured. The difference between found warping and the measured warping is calculated (S4). Whether the difference exceeds a predetermined value is determined (S5). If the difference exceeds a predetermined value, heat treatment conditions are adjusted (S8), but they not adjusted if the difference is no greater than the predetermined value.

Abstract: Exemplary embodiments provide methods and systems for assembling electronic devices, such as integrated circuit (IC) chips, by selectively and seating IC elements onto/into a receiving substrate, such as a chip substrate. Specifically, the assembly of IC chips can include embedding IC elements onto the receiving substrate upon softening the receiving substrate. Such softening can be performed by using a softening agent and/or an activatable thermal barrier material. In an exemplary embodiment, pockets can be formed in the receiving substrate using the activatable thermal barrier material for the IC assembly.

Abstract: According to one exemplary embodiment, a semiconductor die including at least one deep trench isolation region for isolating an electronic device (for example, a bipolar device) includes a trench situated in a substrate of the semiconductor die, where the trench has sides surrounding the electronic device, and where the trench has at least one trench chamfered corner formed between and connecting the sides of the trench. The at least one trench chamferred corner is formed between a chamfered corner of an outside wall of said trench and a corner of an inside wall of the trench. A trench corner width at the at least one trench chamfered corner is less than a trench side width along the sides of the trench.

Abstract: A semiconductor body has a first portion, a second portion, and an active area located between the first portion and the second portion. The first portion and the second portion are a shallow trench isolation region having an exposed surface extending above the surface of the active area. A first ion implantation is performed at a first angle such that a first shaded area defined by the exposed surface of the first portion and the first angle is exposed to fewer ions than a first unshaded area. A second ion implantation is performed at a second angle such that a second shaded area defined by the exposed surface of the second portion and the second angle is exposed to fewer ions than a second unshaded area.

Abstract: Methods and associated structures of forming a microelectronic device are described. Those methods may include implanting the source/drain region, forming a multilayer cap on the source/drain region, annealing the source/drain region, and removing the multilayer cap.

Abstract: Methods of fabricating semiconductor devices are disclosed. An illustrated example method protects spacers and active areas by performing impurity ion implantation on an oxide layer prior to etching the oxide layer. The illustrated method includes forming a gate on a semiconductor substrate, forming a spacer on a sidewall of the gate, forming an oxide layer over the substrate, forming a mask on the oxide layer to cover a non-salicide area, implanting impurity ions into a portion of the oxide layer which is not covered by the mask, removing the portion of the oxide layer which is implanted with impurity ions, performing salicidation on the substrate, and removing the mask.

Abstract: Provided is a nonvolatile semiconductor memory device highly integrated and highly reliable. A plurality of memory cells are formed in a plurality of active regions sectioned by a plurality of isolations (silicon oxide films) extending in the Y direction and deeper than a well (p type semiconductor region). In each memory cell, a contact is provided in the well (p type semiconductor region) so as to penetrate through a source diffusion layer (n+ type semiconductor region), and the contact that electrically connects bit lines (metal wirings) and the source diffusion layer (n+ type semiconductor region) is also electrically connected to the well (p type semiconductor region).