Abstract: A method for manufacturing a dielectric film having a high dielectric constant is provided. The method is a method for forming, on a substrate, a dielectric film including a metal oxide containing O and elements A and B, wherein the element A comprises Hf or a mixture of Hf and Zr and the element B comprises Al or Si, which includes the steps of: forming a metal oxide having an amorphous structure which has a molar ratio between element A and element B, B/(A+B) of 0.02?(B/(A+B))?0.095 and a molar ratio between element A and O, O/A of 1.0<(O/A)<2.0; and annealing the metal oxide having the amorphous structure at 700° C. or more to form a metal oxide containing a crystal phase with a cubic crystal content of 80% or more.

Abstract: A method for fabricating a semiconductor device is described. A stacked gate dielectric is formed over a substrate, including a first dielectric layer, a second dielectric layer and a third dielectric layer from bottom to top. A conductive layer is formed on the stacked gate dielectric and then patterned to form a gate conductor. The exposed portion of the third and the second dielectric layers are removed with a selective wet cleaning step. S/D extension regions are formed in the substrate with the gate conductor as a mask. A first spacer is formed on the sidewall of the gate conductor and a portion of the first dielectric layer exposed by the first spacer is removed. S/D regions are formed in the substrate at both sides of the first spacer. A metal silicide layer is formed on the S/D regions.

Abstract: Semiconductor devices include a semiconductor substrate with a stack structure protruding from the semiconductor substrate and surrounded by an isolation structure. The stack structure includes an active layer pattern and a gap-filling insulation layer between the semiconductor substrate and the active layer pattern. A gate electrode extends from the isolation structure around the stack structure. The gate electrode is configured to provide a support structure for the active layer pattern. The gate electrode may be a gate electrode of a silicon on insulator (SOI) device formed on the semiconductor wafer and the semiconductor device may further include a bulk silicon device formed on the semiconductor substrate in a region of the semiconductor substrate not including the gap-filing insulation layer.

Abstract: A field effect transistor having a gate structure that comprises an interfacial layer positioned in between the transistor channel region and a high-K dielectric layer of the gate stack. The interfacial layer comprises AlxSiyOz, which has a higher relative dielectric constant value than SiO2. A method of forming the gate structure of a field effect transistor. The method includes forming a gate stack comprising, in order: a SiO2-based layer adjacent a channel region of the field effect transistor; a high-K dielectric layer on the SiO2-based layer; and a gate electrode on the high-K dielectric layer. The method also includes introducing Al into the SiO2-based layer to form an AlxSiyOz interfacial layer in between the high-K dielectric layer and the channel region. A heating step to allows Al introduced into channel region to diffuse out of the channel region into the interfacial layer.

Abstract: A first conductive layer and an underlying charge storage layer are patterned to form a control gate in an NVM region. A first dielectric layer is formed over the control gate. A sacrificial layer is formed over the first dielectric layer and planarized. A patterned masking layer is formed over the sacrificial layer which includes a first portion which defines a select gate location laterally adjacent the control gate in the NVM region and a second portion which defines a logic gate in a logic region. Exposed portions of the sacrificial layer are removed such that a first portion remains at the select gate location. A second dielectric layer is formed over the first portion and planarized to expose the first portion. The first portion is removed to result in an opening at the select gate location. A gate dielectric layer and a select gate are formed in the opening.

Abstract: A control gate overlying a charge storage layer is formed. A thermally-grown oxygen-containing layer is formed over the control gate. A polysilicon layer is formed over the oxygen-containing layer and planarized. A first masking layer is formed defining a select gate location laterally adjacent the control gate and a second masking layer is formed defining a logic gate location. Exposed portions of the polysilicon layer are removed such that a select gate remains at the select gate location and a polysilicon portion remains at the logic gate location. A dielectric layer is formed around the select and control gates and polysilicon portion. The polysilicon portion is removed to result in an opening in the dielectric. A high-k gate dielectric and logic gate are formed in the opening.

Abstract: A device having thin-film transistor (TFT) silicon-aluminum oxide-silicon (SAS) memory cell structures is provided. The device includes a substrate, a dielectric layer on the substrate, and one or more source or drain regions being embedded in the dielectric layer. the dielectric layer being associated with a first surface. Each of the one or more source or drain regions includes an N+ polysilicon layer on a diffusion barrier layer which is on a conductive layer. The N+ polysilicon layer has a second surface substantially co-planar with the first surface. Additionally, the device includes a P? polysilicon layer overlying the co-planar surface, an aluminum oxide layer overlying the P? polysilicon layer; and at least one control gate overlying the aluminum oxide layer. In a specific embodiment, the control gate is made of highly doped P+ polysilicon. A method for making the TFT SAS memory cell structure is provided and can be repeated to integrate the structure three-dimensionally.

Abstract: Disclosed are embodiments of an integrated circuit structure that incorporates at least two field effect transistors (FETs) that have the same conductivity type and essentially identical semiconductor bodies (i.e., the same semiconductor material and, thereby the same conduction and valence band energies, the same source, drain, and channel dopant profiles, the same channel widths and lengths, etc.). However, due to different gate structures with different effective work functions, at least one of which is between the conduction and valence band energies of the semiconductor bodies, these FETs have selectively different threshold voltages, which are independent of process variables. Furthermore, through the use of different high-k dielectric materials and/or metal gate conductor materials, the embodiments allow threshold voltage differences of less than 700 mV to be achieved so that the integrated circuit structure can function at power supply voltages below 1.0V.

Abstract: Embodiments of a method of integration of a non-volatile memory device into a MOS flow are described. Generally, the method includes: forming a dielectric stack on a surface of a substrate, the dielectric stack including a tunneling dielectric overlying the surface of the substrate and a charge-trapping layer overlying the tunneling dielectric; forming a cap layer overlying the dielectric stack; patterning the cap layer and the dielectric stack to form a gate stack of a memory device in a first region of the substrate and to remove the cap layer and the charge-trapping layer from a second region of the substrate; and performing an oxidation process to form a gate oxide of a MOS device overlying the surface of the substrate in the second region while simultaneously oxidizing the cap layer to form a blocking oxide overlying the charge-trapping layer. Other embodiments are also disclosed.

Abstract: Storage transistors for flash memory areas in semiconductor devices may be provided on the basis of a self-aligned charge storage region. To this end, a floating spacer element may be provided in some illustrative embodiments, while, in other cases, the charge storage region may be efficiently embedded in the electrode material in a self-aligned manner during a replacement gate approach. Consequently, enhanced bit density may be achieved, since additional sophisticated lithography processes for patterning the charge storage region may no longer be required.

Abstract: This invention concerns an electronic device for the control and readout of the electron or hole spin of a single dopant in silicon. The device comprises a silicon substrate in which there are one or more ohmic contact regions. An insulating region on top of the substrate. First and second barrier gates spaced apart to isolate a small region of charges to form an island of a Single Electron Transistor (SET). A third gate over-lying both the first and second barrier gates, but insulated from them, the third gate being able to generate a gate-induced charge layer (GICL) in the beneath it. A fourth gate in close proximity to a single dopant atom, the dopant atom being encapsulated in the substrate outside the region of the GICL but close enough to allow spin-dependent charge tunnelling between the dopant atom and the SET island under the control of gate potentials, mainly the fourth gate.

Abstract: According to one embodiment, a nonvolatile semiconductor memory device includes a fin structure stacked in order of a first oxide layer, a semiconductor layer and a second oxide layer in a first direction perpendicular to a surface of the semiconductor substrate, the fin structure extending in a second direction parallel to the surface of the semiconductor substrate, and a gate structure stacked in order of a gate oxide layer, a charge storage layer, a block insulating layer and a control gate electrode in a third direction perpendicular to the first and second directions from a surface of the semiconductor layer in the third direction.

Abstract: A semiconductor process includes the following steps. A substrate is provided. An ozone saturated deionized water process is performed to form an oxide layer on the substrate. A dielectric layer is formed on the oxide layer. A post dielectric annealing (PDA) process is performed on the dielectric layer and the oxide layer.

Abstract: A methods of forming a flash memory device are provided. The flash memory device comprises a silicon dioxide layer on a substrate and a silicon nitride layer that is formed on the silicon dioxide layer. The properties of the silicon nitride layer can be modified by any of: exposing the silicon nitride layer to ultraviolet radiation, exposing the silicon nitride layer to an electron beam, and by plasma treating the silicon nitride layer. A dielectric material is deposited on the silicon nitride layer and a conductive date is formed over the dielectric material. The flash memory device with modified silicon nitride layer provides an increase in charge holding capacity and charge retention time of the unit cell of a non-volatile memory device.

Abstract: A gate structure and a method for fabricating the same are described. A substrate is provided, and a gate dielectric layer is formed on the substrate. The formation of the gate dielectric layer includes depositing a silicon nitride layer on the substrate by simultaneously introducing a nitrogen-containing gas and a silicon-containing gas. A gate is formed on the gate dielectric layer, so as to form the gate structure.

Abstract: A method for forming a semiconductor device includes forming a first plurality of nanocrystals over a surface of a substrate having a first region and a second region, wherein the first plurality of nanocrystals is formed in the first region and the second region and has a first density; and, after forming the first plurality of nanocrystals, forming a second plurality of nanocrystals over the surface of the substrate in the second region and not the first region, wherein the first plurality of nanocrystals together with the second plurality of nanocrystals in the second region result in a second density, wherein the second density is greater than the first density.

Abstract: Various methods for protecting a gate structure during contact formation are disclosed. An exemplary method includes: forming a gate structure over a substrate, wherein the gate structure includes a gate and the gate structure interposes a source region and a drain region disposed in the substrate; patterning a first etch stop layer such that the first etch stop layer is disposed on the source region and the drain region; patterning a second etch stop layer such that the second etch stop layer is disposed on the gate structure; and forming a source contact, a drain contact, and a gate contact, wherein the source contact and the drain contact extend through the first etch stop layer and the gate contact extends through the second etch stop layer, wherein the forming the source contact, the drain contact, and the gate contact includes simultaneously removing the first etch stop layer and the second etch stop layer to expose the gate, source region, and drain region.

Abstract: A method of forming a plurality of spaced features includes forming sacrificial hardmask material over underlying material. The sacrificial hardmask material has at least two layers of different composition. Portions of the sacrificial hardmask material are removed to form a mask over the underlying material. Individual features of the mask have at least two layers of different composition, with one of the layers of each of the individual features having a tensile intrinsic stress of at least 400.0 MPa. The individual features have a total tensile intrinsic stress greater than 0.0 MPa. The mask is used while etching into the underlying material to form a plurality of spaced features comprising the underlying material. Other implementations are disclosed.

Abstract: After forming replacement gate structures that are embedded in a planarized dielectric layer on a semiconductor substrate, a contact-level dielectric layer is deposited over a planar surface of the planarized dielectric layer and the replacement gate structures. Substrate contact via holes are formed through the contact-level dielectric layer and the planarized dielectric layer, and metal semiconductor alloy portions are formed on exposed semiconductor materials. Gate contact via holes are subsequently formed through the contact-level dielectric layer. The substrate contact via holes and the gate contact via holes are simultaneously filled with a conductive material to form substrate contact structures and gate contact structures. The substrate contact structures and gate contact structures can be employed to provide local interconnect structures that provide electrical connections between two components that are laterally spaced on the semiconductor substrate.

Abstract: A method of manufacturing flash memory device is provided and includes the following steps. First, a substrate is provided. Then, a stacked gate structure is formed on the substrate. Subsequently, a first oxide layer is formed on the stacked gate structure. Following that, a nitride spacer is formed on the first oxide layer, wherein a nitrogen atom-introducing treatment is performed after the forming of the first oxide layer and before the forming of the nitride spacer. Accordingly, the nitrogen atom-introducing treatment of the presentation invention can improve the data retention reliability of the flash memory device.

Abstract: A semiconductor device, includes a semiconductor layer formed above a substrate; an insulating film formed on the semiconductor layer; and an electrode formed on the insulating film. The insulating film has a membrane stress at a side of the semiconductor layer lower than a membrane stress at a side of the electrode.

Abstract: A manufacturing method for a metal gate includes providing a substrate having a dielectric layer and a polysilicon layer formed thereon, the polysilicon layer, forming a protecting layer on the polysilicon layer, forming a patterned hard mask on the protecting layer, performing a first etching process to etch the protecting layer and the polysilicon layer to form a dummy gate having a first height on the substrate, forming a multilayered dielectric structure covering the patterned hard mask and the dummy gate, removing the dummy gate to form a gate trench on the substrate, and forming a metal gate having a second height in the gate trench. The second height of the metal gate is substantially equal to the first height of the dummy gate.

Abstract: Methods for forming a memory cell are disclosed. A method includes forming a source-drain structure in a semiconductor substrate where the source-drain structure includes a rounded top surface and sidewall surfaces. An oxide layer is formed on the top and sidewall surfaces of the source-drain structure. The thickness of the portion of the oxide layer that is formed on the top surface of the source-drain structure is greater than the thickness of the portion of the oxide layer that is formed on the sidewall surfaces of the source-drain structure.

Abstract: Disclosed herein is a method for manufacturing an insulated gate field effect transistor, the method including the steps of: (a) preparing a base that includes source/drain regions, a channel forming region, a gate insulating film formed on the channel forming region, an insulating layer covering the source/drain regions, and a gate electrode formation opening provided in a partial portion of the insulating layer above the channel forming region; (b) forming a gate electrode by burying a conductive material layer in the gate electrode formation opening; (c) removing the insulating layer; and (d) depositing a first interlayer insulating layer and a second interlayer insulating layer sequentially across an entire surface, wherein in the step (d), the first interlayer insulating layer is deposited in a deposition atmosphere containing no oxygen atom.

Abstract: An embodiment of a method of integration of a non-volatile memory device into a logic MOS flow is described. Generally, the method includes: forming a pad dielectric layer of a MOS device above a first region of a substrate; forming a channel of the memory device from a thin film of semiconducting material overlying a surface above a second region of the substrate, the channel connecting a source and drain of the memory device; forming a patterned dielectric stack overlying the channel above the second region, the patterned dielectric stack comprising a tunnel layer, a charge-trapping layer, and a sacrificial top layer; simultaneously removing the sacrificial top layer from the second region of the substrate, and the pad dielectric layer from the first region of the substrate; and simultaneously forming a gate dielectric layer above the first region of the substrate and a blocking dielectric layer above the charge-trapping layer.

Abstract: An embodiment of a method of integrating a non-volatile memory device into a logic MOS flow is described. Generally, the method includes: forming in a first region of a substrate a channel of a memory device from a semiconducting material overlying a surface of the substrate, the channel connecting a source and a drain of the memory device; forming a charge trapping dielectric stack over the channel adjacent to a plurality of surfaces of the channel, wherein the charge trapping dielectric stack includes a blocking layer on a charge trapping layer over a tunneling layer; and forming a MOS device over a second region of the substrate.

Abstract: Embodiments of a non-planar memory device including a split charge-trapping region and methods of forming the same are described. Generally, the device comprises: a channel formed from a thin film of semiconducting material overlying a surface on a substrate connecting a source and a drain of the memory device; a tunnel oxide overlying the channel; a split charge-trapping region overlying the tunnel oxide, the split charge-trapping region including a bottom charge-trapping layer comprising a nitride closer to the tunnel oxide, and a top charge-trapping layer, wherein the bottom charge-trapping layer is separated from the top charge-trapping layer by a thin anti-tunneling layer comprising an oxide. Other embodiments are also disclosed.

Abstract: According to one embodiment, a nonvolatile semiconductor memory device includes a source region and a drain region provided on a surface area of a semiconductor region, a tunnel insulating film provided on a channel between the source region and the drain region, a charge storage layer provided on the tunnel insulating film, a first dielectric film provided on the charge storage layer and containing lanthanum aluminum silicon oxide or oxynitride, a second dielectric film provided on the first dielectric film and containing oxide or oxynitride containing at least one of hafnium (Hf), zirconium (Zr), titanium (Ti), and a rare earth metal, and a control gate electrode provided on the second dielectric film.

Abstract: The present invention provides a method and apparatus for manufacturing a semiconductor device using a PVD method and enabling achievement of a desired effective work function and reduction in leak current without increasing an equivalent oxide thickness. A method for manufacturing a semiconductor device in an embodiment of the present invention includes the steps of: preparing a substrate on which an insulating film having a relative permittivity higher than that of a silicon oxide film is formed; and depositing a metal nitride film on the insulating film. The metal nitride depositing step is a step of sputtering deposition in an evacuatable chamber using a metal target and a cusp magnetic field formed over a surface of the metal target by a magnet mechanism in which magnet pieces are arranged as grid points in such a grid form that the adjacent magnet pieces have their polarities reversed from each other.

Abstract: A semiconductor structure, and method of forming a semiconductor structure, that includes a gate structure on a semiconductor substrate, in which the gate structure includes a gate conductor and a high-k gate dielectric layer. The high-k gate dielectric layer is in contact with the base of the gate conductor and is present on the sidewalls of the gate conductor for a dimension that is less than ¼ the gate structure's height. The semiconductor structure also includes source regions and drain regions present in the semiconductor substrate on opposing sides of the gate structure.

Abstract: Devices, memory arrays, and methods are disclosed. In an embodiment, one such device has a source/drain zone that has first and second active regions, and an isolation region and a dielectric plug between the first and second active regions. The dielectric plug may extend below upper surfaces of the first and second active regions and may be formed of a dielectric material having a lower removal rate than a dielectric material of the isolation region for a particular isotropic removal chemistry.

Abstract: A method for fabricating an integrated circuit device is disclosed. An exemplary method includes providing a substrate; forming a high-k dielectric layer over the substrate; forming a first capping layer over the high-k dielectric layer; forming a second capping layer over the first capping layer; forming a dummy gate layer over the second capping layer; performing a patterning process to form a gate stack including the high-k dielectric layer, first and second capping layers, and dummy gate layer; removing the dummy gate layer from the gate stack, thereby forming an opening that exposes the second capping layer; and filling the opening with a first metal layer over the exposed second capping layer and a second metal layer over the first metal layer, wherein the first metal layer is different from the second metal layer and has a work function suitable to the semiconductor device.

Abstract: A high voltage power semiconductor device includes high reliability-high voltage junction termination with a charge dissipation layer. An active device area is surrounded by a junction termination structure including one or more regions of a polarity opposite the substrate polarity. A tunneling oxide layer overlays the junction termination area surrounding the active device area in contact with the silicon substrate upper surface. A layer of undoped polysilicon overlays the tunneling oxide layer and spans the junction termination area, with connections to an outer edge of the junction termination structure and to a grounded electrode inside of the active area. The tunneling oxide layer has a thickness that permits hot carriers formed at substrate upper surface to pass through the tunneling oxide layer into the undoped polysilicon layer to be dissipated but sufficient to mitigate stacking faults at the silicon surface.

Abstract: Transistors are provided including first and second source/drain regions, a channel region and a gate stack having a first gate dielectric over a substrate, the first gate dielectric having a dielectric constant higher than a dielectric constant of silicon dioxide, and a metal material in contact with the first gate dielectric, the metal material being doped with an inert element. Integrated circuits including the transistors and methods of forming the transistors are also provided.

Abstract: Disclosed is semiconductor structure with an insulator layer on a semiconductor substrate and a device layer is on the insulator layer. The substrate is doped with a relatively low dose of a dopant having a given conductivity type such that it has a relatively high resistivity. Additionally, a portion of the semiconductor substrate immediately adjacent to the insulator layer can be doped with a slightly higher dose of the same dopant, a different dopant having the same conductivity type or a combination thereof. Optionally, micro-cavities are created within this same portion so as to balance out any increase in conductivity due to increased doping with a corresponding increase in resistivity. Increasing the dopant concentration at the semiconductor substrate-insulator layer interface raises the threshold voltage (Vt) of any resulting parasitic capacitors and, thereby reduces harmonic behavior. Also disclosed herein are embodiments of a method for forming such a semiconductor structure.

Abstract: Monolithic, three dimensional NAND strings include a semiconductor channel, at least one end portion of the semiconductor channel extending substantially perpendicular to a major surface of a substrate, a plurality of control gate electrodes having a strip shape extending substantially parallel to the major surface of the substrate, the blocking dielectric comprising a plurality of blocking dielectric segments, a plurality of discrete charge storage segments, and a tunnel dielectric located between each one of the plurality of the discrete charge storage segments and the semiconductor channel.

Abstract: One object of one embodiment of the present invention is to provide a highly reliable semiconductor device including an oxide semiconductor, which has stable electrical characteristics. In a method for manufacturing a semiconductor device, a first insulating film is formed; source and drain electrodes and an oxide semiconductor film electrically connected to the source and drain electrodes are formed over the first insulating film; heat treatment is performed on the oxide semiconductor film so that a hydrogen atom in the oxide semiconductor film is removed; oxygen doping treatment is performed on the oxide semiconductor film, so that an oxygen atom is supplied into the oxide semiconductor film; a second insulating film is formed over the oxide semiconductor film; and a gate electrode is formed over the second insulating film so as to overlap with the oxide semiconductor film.

Abstract: A semiconductor device is provided that, in an embodiment, is in the form of a high voltage MOS (HVMOS) device. The device includes a semiconductor substrate and a gate structure formed on the semiconductor substrate. The gate structure includes a gate dielectric which has a first portion with a first thickness and a second portion with a second thickness. The second thickness is greater than the first thickness. A gate electrode is disposed on the first and second portion. In an embodiment, a drift region underlies the second portion of the gate dielectric. A method of fabricating the same is also provided.

Abstract: A charge storage layer interposed between a memory gate electrode and a semiconductor substrate is formed shorter than a gate length of the memory gate electrode or a length of insulating films so as to make the overlapping amount of the charge storage layer and a source region to be less than 40 nm. Therefore, in the write state, since the movement in the transverse direction of the electrons and the holes locally existing in the charge storage layer decreases, the variation of the threshold voltage when holding a high temperature can be reduced. In addition, the effective channel length is made to be 30 nm or less so as to reduce an apparent amount of holes so that coupling of the electrons with the holes in the charge storage layer decreases; therefore, the variation of the threshold voltage when holding at room temperature can be reduced.

Abstract: A non-volatile memory device includes field insulating layer patterns on a substrate to define an active region of the substrate, upper portions of the field insulating layer patterns protruding above an upper surface of the substrate, a tunnel insulating layer on the active region, a charge trapping layer on the tunnel insulating layer, a blocking layer on the charge trapping layer, first insulating layers on upper surfaces of the field insulating layer patterns, and a word line structure on the blocking layer and first insulating layers.

Abstract: A method for forming a hydrogen barrier liner for a ferro-electric random access memory chip including forming a first dielectric layer over a substrate; forming a gate over the first dielectric layer; forming a first aluminum oxide layer over the gate and the first dielectric layer; forming a second dielectric layer over the first aluminum oxide layer; etching a trench through the second dielectric layer and the first aluminum oxide layer to the gate; forming a hydrogen barrier liner over the second dielectric layer, the hydrogen barrier liner lining the trench and contacting the gate; forming a silicon dioxide layer over the first aluminum dioxide layer, the silicon dioxide layer substantially filling the trench; and substantially removing the silicon dioxide layer leaving a silicon dioxide plug in the trench.

Abstract: A method includes forming a gate dielectric over a substrate in an NVM region and a logic region; forming a first conductive layer over the gate dielectric in the NVM region and the logic region; patterning the first conductive layer in the NVM region to form a select gate; forming a charge storage layer over the select gate in the NVM region and the first conductive layer in the logic region; forming a second conductive layer over the charge storage layer in the NVM region and the logic region; removing the second conductive layer and the charge storage layer from the logic region; patterning the first conductive layer in the logic region to form a first logic gate; and after forming the first logic gate, patterning the second conductive layer in the NVM region to form a control gate which overlaps a sidewall of the select gate.

Abstract: There is provided a fin transistor structure and a method of fabricating the same. The fin transistor structure comprises a fin formed on a semiconductor substrate, wherein a bulk semiconductor material is formed between a portion of the fin serving as the channel region of the transistor structure and the substrate, and an insulation material is formed between remaining portions of the fin and the substrate. Thereby, it is possible to reduce the current leakage while maintaining the advantages of body-tied structures.

Abstract: An active matrix substrate includes: pixel regions (5L, 5R, and 5M) provided in line and column direction; scan signal lines (16? and 16?); data signal lines (Sp, Sq, sp, and sq) crossing the scan signal lines at right angles; a gate insulating film covering the scan signal lines; and an interlayer insulating film covering the data signal lines, two of the data signal lines (Sq and sp) being provided (i) so as to overlap a gap between two of the pixel regions (5L and 5R) which are adjacent to each other in the line direction or (ii) so as to overlap a region which extends along the gap, the interlayer insulating film having a hollow part K so that the hollow part K and a gap between the two of the data signal lines (Sq and sp) overlap each other, and part of the hollow part K and the scan signal lines (16? and 16?) overlap each other via the gate insulating film.

Abstract: A semiconductor device including a germanium containing substrate including a gate structure on a channel region of the semiconductor substrate. The gate structure may include a silicon oxide layer that is in direct contact with an upper surface of the germanium containing substrate, at least one high-k gate dielectric layer in direct contact with the silicon oxide layer, and at least one gate conductor in direct contact with the high-k gate dielectric layer. The interface between the silicon oxide layer and the upper surface of the germanium containing substrate is substantially free of germanium oxide. A source region and a drain region may be present on opposing sides of the channel region.

Abstract: Sophisticated gate electrode structures for N-channel transistors and P-channel transistors are patterned on the basis of substantially the same configuration while, nevertheless, the work function adjustment may be accomplished in an early manufacturing stage. For this purpose, diffusion layer and cap layer materials are removed after incorporating the desired work function metal species into the high-k dielectric material and subsequently a common gate layer stack is deposited and subsequently patterned.

Abstract: In one embodiment, a method of manufacturing a nonvolatile semiconductor memory includes forming a plurality of memory cell transistors and a plurality of selection transistors on a substrate. The method further includes burying first and second insulators successively between memory cell transistors and between a memory cell transistor and a selection transistor, and forming the first and second insulators successively on side surfaces of selection transistors, the side surfaces facing a space between the selection transistors. The method further includes burying third to fifth insulators successively between the selection transistors via the first and second insulators. The method further includes removing the second and fourth insulators by a first etching so that the second and fourth insulators partially remain between the selection transistors.

Abstract: There is provided a fin transistor structure and a method of fabricating the same. The fin transistor structure comprises a fin formed on a semiconductor substrate, wherein an insulation material is formed between a portion of the fin serving as the channel region of the transistor structure and the substrate, and a bulk semiconductor material is formed between remaining portions of the fin and the substrate. Thereby, it is possible to reduce the current leakage while maintaining the advantages such as low cost and high heat transfer.

Abstract: A memory device, a manufacturing method and an operating method of the same are provided. The memory device includes a substrate, stacked structures, a channel element, a dielectric element, a source element, and a bit line. The stacked structures are disposed on the substrate. Each of the stacked structures includes a string selection line, a word line, a ground selection line and an insulating line. The string selection line, the word line and the ground selection line are separated from each other by the insulating line. The channel element is disposed between the stacked structures. The dielectric element is disposed between the channel element and the stacked structure. The source element is disposed between the upper surface of the substrate and the lower surface of the channel element. The bit line is disposed on the upper surface of the channel element.

Abstract: A memory array includes a plurality of bit lines and a plurality of word lines, a gate region, and a charge trapping layer. The charge trapping layer is wider than a word line; the charge trapping layer is extended beyond the edge of the gate region to facilitate capturing and removing charges.