Abstract: A semiconductor memory device includes a plurality of transistors on a semiconductor substrate; a first interlayer dielectric film on the transistors; a plurality of ferroelectric capacitors on the first interlayer dielectric film; a first hydrogen barrier film covering an upper surface and a side surface of each of the ferroelectric capacitors; a second interlayer dielectric film above the ferroelectric capacitors, the second interlayer dielectric film being buried to have a void or hole between two adjacent ferroelectric capacitors out of the ferroelectric capacitors; a cover dielectric film covering the second interlayer dielectric film to close an opening of the void or hole; and a second hydrogen barrier film covering the cover dielectric film.

Abstract: A semiconductor device includes a plurality of conduction plugs disposed on an active region, a bit line connected to a conduction plug of the plurality of conduction plugs which is disposed in a central portion of the active region, and storage nodes connected with conduction plugs of the plurality of conduction plugs which are disposed at both peripherals of the active region and passing over the active region.

Abstract: In Trench-Gate Fin-FET, in order that the advantage which is exerted in Fin-FET can be sufficiently taken even if a transistor becomes finer and, at the same time, decreasing of on-current can be suppressed by saving a sufficiently large contact area in the active region, a fin width 162 of a channel region becomes smaller than a width 161 of an active region.

Abstract: In a method of manufacturing a semiconductor device, first contact holes reaching diffusion regions of a cell transistor, bit line contact holes reaching diffusion regions of the cell transistor, and interconnect grooves communicating with the bit line contact holes are buried in a first insulating film. In addition, first contact plugs and bit line contacts are respectively formed by burying conductive materials in the first contact holes, the bit line contact holes and the interconnect grooves, and the first contact plugs are electrically connected to a capacitor formed in a third insulating film through an opening formed in a second insulating film.

Abstract: A method for forming a memory cell transistor is disclosed which includes providing a substrate, forming a trench structure in the substrate, depositing a conductive substance on the surface of the substrate to form a conductive member inside the trench structure, forming one or more dielectric layers on the surface of the substrate, forming one or more first conductive layers on top of the dielectric layers, and etching the first conductive layers and the dielectric layers to form a hole structure extending through the first conductive and the dielectric layers, reaching to the substrate surface. The formed memory cell transistor thus comprises a hole structure which is formed from the surface of the top first conductive layer, extending downwards through the first conductive layers and the dielectric layers, and reaching the substrate surface. One or more second conductive layers may be formed on top of the first conductive layers, with the second conductive layer material filling the hole structure.

Abstract: Provided are semiconductor devices including a semiconductor substrate, an insulating layer including a contact hole through which the semiconductor substrate is exposed, and a polysilicon layer filling the contact hole. The polysilicon layer is doped with impurities and includes an impurity-diffusion prevention layer. In the semiconductor devices, the impurities included in the polysilicon layer do not diffuse into the insulating layer and the semiconductor substrate due to the impurity-diffusion prevention layers.

Abstract: A memory cell, array and device include an active area formed in a substrate with a vertical transistor including a first end disposed over a first portion of the active area. The vertical transistor is formed as an epitaxial post on the substrate surface, extends from the surface of the substrate, and includes a gate formed around a perimeter of the epitaxial post. A capacitor is formed on the vertical transistor and a buried digit line vertically couples to a second portion of the active area. An electronic system and method for forming a memory cell are also disclosed.

Abstract: A method for forming a memory device in a semiconductor on insulator substrate is provided, in which a protective oxide that is present on the sidewalls of the trench protects the first semiconductor layer, i.e., SOI layer, of the semiconductor on insulator substrate during bottle etching of the trench. In one embodiment, the protective oxide reduces back channel effects of the transistors to the memory devices in the trench that are formed in the semiconductor on insulator substrate. In another embodiment, a thermal oxidation process increases the thickness of the buried dielectric layer of a bonded semiconductor on insulator substrate by oxidizing the bonded interface between the buried dielectric layer and at least one semiconductor layers of the semiconductor on insulator substrate. The increased thickness of the buried dielectric layer may reduce back channel effects in devices formed on the substrate having trench memory structures.

Abstract: A dynamic random access memory cell including a bottom oxide layer, a first semiconductor layer, a second semiconductor layer, an insulation layer, a gate and a doping layer is provided. The bottom oxide layer is disposed on a substrate. The first semiconductor layer disposed on the bottom oxide layer has a first doping concentration. The second semiconductor layer disposed on the first semiconductor layer has a second doping concentration lower than the first doping concentration. The insulation layer disposed on the bottom oxide layer at least situates at the two sides of the first semiconductor layer. The height of the insulation layer is greater than that of the first semiconductor layer. The gate is disposed on the second semiconductor layer. The doping layer disposed correspondingly to the two sides of the gate substantially contacts the second semiconductor layer and the insulation layer.

Abstract: A semiconductor structure includes a first conductive layer coupled to a transistor. A first dielectric layer is over the first conductive layer. A second conductive layer is within the first dielectric layer, contacting a portion of a top surface of the first conductive layer. The second conductive layer includes a cap portion extending above a top surface of the first dielectric layer. A first dielectric spacer is between the first dielectric layer and the second conductive layer. A phase change material layer is above a top surface of the second conductive layer. A third conductive layer is over the phase change material layer. A second dielectric layer is over the first dielectric layer. A second dielectric spacer is on a sidewall of the cap portion, wherein a thermal conductivity of the second dielectric spacer is less than that of the first dielectric layer or that of the second dielectric layer.

Abstract: A capacitor for a semiconductor device having a dielectric film between an upper electrode and a lower electrode is featured in that the dielectric film includes an alternately laminated film of hafnium oxide and titanium oxide at an atomic layer level.

Abstract: A trench structure and a memory cell using the trench structure. The trench structure includes: a substrate; a trench having contiguous upper, middle and lower regions, the trench extending from a top surface of said substrate into said substrate; the upper region of the trench having a vertical sidewall profile; and the middle region of the trench having a tapered sidewall profile.

Abstract: In a semiconductor integrated circuit device and a method of formation thereof, a semiconductor device comprises: a semiconductor substrate; an insulator at a top portion of the substrate, defining an insulator region; a conductive layer pattern on the substrate, the conductive layer pattern being patterned from a common conductive layer, the conductive layer pattern including a first pattern portion on the insulator in the insulator region and a second pattern portion on the substrate in an active region of the substrate, wherein the second pattern portion comprises a gate of a transistor in the active region; and a capacitor on the insulator in the insulator region, the capacitor including: a lower electrode on the first pattern portion of the conductive layer pattern, a dielectric layer pattern on the lower electrode, and an upper electrode on the dielectric layer pattern.

Abstract: A DRAM array having trench capacitor cells of potentially 4F2 surface area (F being the photolithographic minimum feature width), and a process for fabricating such an array. The array has a cross-point cell layout in which a memory cell is located at the intersection of each bit line and each word line. Each cell in the array has a vertical device such as a transistor, with the source, drain, and channel regions of the transistor being formed from epitaxially grown single crystal silicon. The vertical transistor is formed above the trench capacitor.

Abstract: The present invention proposes a semiconductor device, its manufacturing method and to an electronic apparatus thereof equipped with the semiconductor device where it becomes possible to make a CMOS type solid-state imaging device, an imager area formed with a MOS transistor of an LDD structure without having a metal silicide layer of a refractory metal, an area of DRAM cells and the like into a single semiconductor chip. According to the present invention, a semiconductor device is constituted such that an insulating film having a plurality of layers is used, sidewalls at the gate electrodes are formed by etching back the insulating film of the plurality of layers or a single layer film in the region where metal silicide layers are formed and in the region where the metal silicide layers are not formed, sidewalls composed of an upper layer insulating film is formed on a lower layer insulating film whose surface is coated or the insulating film of the plurality of layers remain unchanged.

Abstract: The chip area of a semiconductor device including a nonvolatile memory is reduced. The semiconductor device includes a first memory cell and a second memory cell which are formed on the principal surface of a substrate, and arranged adjacent to each other. In a principal surface of the substrate, active regions which are electrically isolated from each other are arranged. In the first active region, the capacitor element of the first memory cell is arranged, while the capacitor element of the second memory cell is arranged in the fourth active region. In the second active region, the respective write/erase elements of the first and second memory cells are both arranged. Further, in the third active region, the respective read elements of the first and second memory cells are both arranged.

Abstract: A method for manufacturing a semiconductor device that is less prone to DC failures brought about by unwanted defects on capacitors in the device is presented. Manufacturing defects such as scratches are known to occur when making capacitors and that these defects are thought to be a primary cause of subsequent performance DC failures in the completed semiconductor devices. The method includes the steps of depositing, removing, forming, polishing, etching and forming. A sacrificial layer is exploited to allow a subsequent polishing down step to mechanically remove defects from the capacitors.

Abstract: A FinFET includes a fin that is on a substrate and extends away from the substrate. A device isolation layer is disposed on the substrate on both sides of the fin. An insulating layer is between the fin and the substrate. The insulating layer is directly connected to the device isolation layer and has a different thickness than the device isolation layer. A gate electrode crosses over the fin. A gate insulating layer is between the gate electrode and the fin. Source and drain regions are on the fins and on opposite sides of the gate electrode. Related nonvolatile memory devices that include FinFETs and methods of making FinFETs and nonvolatile memory devices are also disclosed.

Abstract: The invention includes a method of forming a semiconductor construction. Dopant is implanted into the upper surface of a monocrystalline silicon substrate. The substrate is etched to form a plurality of trenches and cross-trenches which define a plurality of pillars. After the etching, dopant is implanted within the trenches to form a source/drain region that extends less than an entirety of the trench width. The invention includes a semiconductor construction having a bit line disposed within a semiconductor substrate below a first elevation. A wordline extends elevationally upward from the first elevation and substantially orthogonal relative to the bit line. A vertical transistor structure is associated with the wordline. The transistor structure has a channel region laterally surrounded by a gate layer and is horizontally offset relative to the bit line.

Abstract: An integrated circuit device includes a device isolation pattern on a semiconductor substrate to define an active area therein. The active area includes a doped region therein. A conductive pattern extends on the active area and electrically contacts the doped region. The conductive pattern has a lower resistivity than the doped region. The conductive pattern may be disposed in a recessed region having a bottom surface lower than a top surface of the active area. A channel pillar electrically contacts to the doped region and extends therefrom in a direction away from the substrate. A conductive gate electrode is disposed on a sidewall of the channel pillar, and a gate dielectric layer is disposed between the gate electrode and the sidewall of the channel pillar.

Abstract: A semiconductor memory device including: word lines extending in a Y direction on a semiconductor substrate, the word lines being arranged in an X direction perpendicular to the Y direction and being parallel to one another; active regions each elongating and intersecting with two of the word lines, the active regions being arranged in the Y direction and being parallel to one another on the semiconductor substrate; a capacitance contact plug connected to each end of each of the active regions in the longitudinal direction thereof; a stack lower electrode including a first lower electrode formed on the capacitance contact plug and a second lower electrode formed on the first lower electrode; a capacitance insulating film; and an upper electrode, wherein the center position of the second lower electrode is shifted in a predetermined direction from the center position of the first lower electrode.

Abstract: In a complete CMOS SRAM having a memory cell composed of six MISFETs formed over a substrate, a capacitor element having a stack structure is formed of a lower electrode covering the memory cell, an upper electrode, and a capacitor insulating film (dielectric film) interposed between the lower electrode and the upper electrode. One electrode (the lower electrode) of the capacitor element is connected to one storage node of a flip-flop circuit, and the other electrode (the upper electrode) is connected to the other storage node. As a result, the storage node capacitance of the memory cell of the SRAM is increased to improve the soft error resistance.

Abstract: The invention includes a transistor device having a semiconductor substrate with an upper surface. A pair of source/drain regions are formed within the semiconductor substrate and a channel region is formed within the semiconductor substrate and extends generally perpendicularly relative to the upper surface of the semiconductor substrate. A gate is formed within the semiconductor substrate between the pair of the source/drain regions.

Abstract: A PRAM and a fabricating method thereof are provided. The PRAM includes a transistor and a data storage capability. The data storage capability is connected to the transistor. The data storage includes a top electrode, a bottom electrode, and a porous PCM layer. The porous PCM layer is interposed between the top electrode and the bottom electrode.

Abstract: A DRAM device includes a plug on a substrate, a conductive plate electrically connected to the plug and overlapping the substrate, at least one capacitor on the substrate and spaced apart from the plug, and at least one word line under the conductive plate and spaced apart from the conductive plate. The DRAM device further includes at least one first conductive pad under the conductive plate, the at least one first conductive pad being spaced apart from the conductive plate in a first state and being electrically connected to the conductive plate in a second state, the at least one first conductive pad being disposed between the plug and an adjacent word line of the at least one word line, and the at least one first conductive pad being electrically connected to a respective capacitor of the at least one capacitor.

Abstract: A read only memory is manufactured with a plurality of transistors (4) on a semiconductor substrate (2). A low-k dielectric (10) and interconnects (14) are provided over the transistors (4). To program the read only memory, the low-k dielectric is implanted with ions (22) in unmasked regions (20) leaving the dielectric unimplanted in masked regions (18). The memory thus formed is difficult to reverse engineer.

Abstract: Techniques for providing a semiconductor memory device are disclosed. In one particular exemplary embodiment, the techniques may be realized as an apparatus including a first region and a second region. The apparatus may also include a body region disposed between the first region and the second region and capacitively coupled to a plurality of word lines, wherein each of the plurality of word lines is capacitively coupled to different portions of the body region.

Abstract: A semiconductor device, having a memory cell region and a peripheral circuit region, includes an insulating film, having an upper surface, formed on a major surface of a semiconductor substrate to extend from the memory cell region to the peripheral circuit region. A capacitor lower electrode assembly is formed in the memory cell region to upwardly extend to substantially the same height as the upper surface of the insulating film on the major surface of the semiconductor substrate. Additionally, the lower electrode assembly includes first and second lower electrodes that are adjacent through the insulating film. A capacitor upper electrode is formed on the capacitor lower electrode through a dielectric film, to extend onto the upper surface of the insulating film. The capacitor lower electrode includes a capacitor lower electrode part having a top surface and a bottom surface.

Abstract: Some embodiments include memory cells that contain floating bodies and diodes. The diodes may be gated diodes having sections doped to a same conductivity type as the floating bodies, and such sections of the gated diodes may be electrically connected to the floating bodies. The floating bodies may be adjacent channel regions, and spaced from the channel regions by a dielectric structure. The dielectric structure of a memory cell may have a first portion between the floating body and the diode, and may have a second portion between the floating body and the channel region. The first portion may be more leaky to charge carriers than the second portion. The diodes may be formed in semiconductor material that is different from a semiconductor material that the channel regions are in. The floating bodies may have bulbous lower regions. Some embodiments include methods of making memory cells.

Abstract: Disclosed herein is a semiconductor memory device including plural unit cells, each constituted with a floating body transistor without any capacitor, to prevent data distortion and data crash in the unit cell. A semiconductor memory device comprises plural active regions and a device isolation layer for separating each active region from each others, wherein the plural active regions stand in row and column lines.

Abstract: Disclosed are embodiments for a container capacitor structure in which at least two container capacitors, e.g., an inner and outer container capacitor, are made concentric and nested with respect to one another. The nested capacitors are formed in one embodiment by defining a hole in a dielectric layer for the nested container capacitors in the vicinity of two capacitor contact plugs. An outer capacitor plate is formed by etching back poly 1 to leave it substantially on the vertical edges of the hole and in contact with one of the plugs. At least one sacrificial sidewall is formed on the poly 1, and poly 2 is deposited over the sidewalls to form an inner capacitor plate in contact with the other plug. The structure is planarized, the sacrificial sidewalls are removed, a capacitor dielectric is formed, and is topped with poly 3. Additional structures such as a protective layer (to prevent poly 1-to-poly 2 shorting) and a conductive layer (to strap the plugs to their respective poly layers) can also be used.

Abstract: Some embodiments include apparatus and methods having a base; a memory cell including a body, a source, and a drain; and an insulation material electrically isolating the body, the source, and the drain from the base, where the body is configured to store information. The base and the body include bulk semiconductor material. Additional apparatus and methods are described.

Abstract: A dummy transistor and a field effect transistor are arranged in a second direction. The dummy transistor is located at least at one end in a second direction.

Abstract: A semiconductor device according to an exemplary embodiment of the present invention includes a memory cell including an information storage portion including a capacitor upper electrode of a DRAM cell and a capacitor lower electrode formed below the upper electrode and an access transistor for controlling access to the information storage portion, a bit-line connected to the access transistor to write or read data to or from the information storage portion, a word line connected to a gate electrode of the access transistor to control the access transistor, and a capacitive element including an upper electrode made from a same layer as a first metal line formed above the capacitor upper electrode and a lower electrode made from a same layer as the capacitor upper electrode, the capacitive element being formed outside an area where the memory cell is formed.

Abstract: A memory cell capacitor (C3) of a DRAM is formed by use of a MIM capacitor which uses as its electrode a metal wiring line of the same layer (M3) as metal wiring lines within a logic circuit (LOGIC), thereby enabling reduction of process costs. Higher integration is achievable by forming the capacitor using a high dielectric constant material and disposing it above a wiring layer in which bit lines (BL) are formed. In addition, using 2T cells makes it possible to provide a sufficient signal amount even when letting them operate with a low voltage. By commonizing the processes for fabricating capacitors in analog (ANALOG) and memory (MEM), it is possible to realize a semiconductor integrated circuit with the logic, analog and memory mounted together on one chip at low costs.

Abstract: A semiconductor device includes a semiconductor chip including an interlayer insulating film, a first area, and a first crack stopper. The first area includes a plurality of capacitors, each of which includes a lower electrode and a dielectric film sequentially formed on the inner wall of a first opening and an upper electrode buried in the first opening, and a plate electrode provided to be electrically connected to the upper electrode of each of the capacitors. The first crack stopper includes first and second films sequentially formed on the inner wall of a second opening, a third film buried in the second opening, and an upper area provided to be in contact with the third film.

Abstract: The present invention relates to a memory cell with a memory capacitor (110) on an active semiconductor region (104), the memory capacitor having a first capacitor-electrode layer, which, in a cross-sectional view of the memory cell, has first (218.1) and second (218.2) electrode-layer sections that extend on the active semiconductor region in parallel to the surface of the active semiconductor region at a vertical distance to each other and that are electrically connected by a third electrode-layer section extending vertically, that is, perpendicular to the surface of the active semiconductor region. A control transistor (112) is connected with a conductive second capacitor electrode layer that extends between the first and second electrode-layer sections and is electrically isolated from them by an isolation layer (116). Achieved advantages comprise a high manufacturing yield can, reduced fabrication cost and reduced risk of junction leakage by a small area required for the memory cell.

Abstract: Borderless contacts for word lines or via contacts for bit lines are formed using interconnect patterns, a part of which is removed. A semiconductor memory includes: a plurality of active regions AAi, AAi+1, . . . , AAn, which extend on a memory cell array along the column length; a plurality of word line patterns WL1, WL2, . . . , extend along the row length and are non-uniformly arranged; a plurality of select gate line patterns SG1, SG2, . . . , are arranged parallel to the plurality of word line patterns; borderless contacts are formed near the ends of the word line patterns on the memory cell array, and are in contact with part of an interconnect extended from the end of the memory cell array, but are not in contact with interconnects adjacent to that interconnect; and bit line contacts are formed within contact forming regions provided by removing part of the plurality of word line patterns and select gate line patterns through double exposure.

Abstract: According to an aspect of the present invention, there is provided a nonvolatile semiconductor memory device including: a semiconductor substrate; memory cell transistors that are series-connected; and a select transistor that includes: a first diffusion region that is formed in the semiconductor substrate at one end of the memory cell transistors; a first insulating film that is formed on the semiconductor substrate at a side of the first diffusion region; a select gate electrode that is formed on the first insulating film; a semiconductor pillar that is formed to extend upward from the semiconductor substrate and to be separated from the select gate electrode; a second insulating film that is formed between the select gate electrode and the semiconductor pillar; and a second diffusion region that is formed on the semiconductor pillar.

Abstract: Some embodiments include DRAM having transistor gates extending partially over SOI, and methods of forming such DRAM. Unit cells of the DRAM may be within active region pedestals, and in some embodiments the unit cells may comprise capacitors having storage nodes in direct contact with sidewalls of the active region pedestals. Some embodiments include 0C1T memory having transistor gates entirely over SOI, and methods of forming such 0C1T memory.

Abstract: A device manufacturing method includes forming a first insulation film on a semiconductor substrate. A first mask is formed on the first insulation film to extend in a first direction and have a linear pattern. The first insulation film is etched using the first mask as mask to process the insulation film into a linear body. A second mask is formed on the linear body to extend in a second direction different from the first direction and have a linear pattern. The linear body is etched using the second mask as mask to process the linear body into a pillar element. A first conductive film is formed to cover the pillar body. The first conductive film is etched to form a first electrode of the first conductive film on side surfaces of the pillar body.

Abstract: The semiconductor device includes a first conductor formed over a semiconductor substrate; a first insulator formed over the first conductor; a second insulator formed over the first insulator, the second insulator having an etching characteristic different from an etching characteristic of the first insulator; a second conductor formed on the second insulator, the second conductor being in contact with the second insulator; a third insulator formed over the second conductor, the third insulator having an etching characteristic different from the etching characteristic of the second insulator; a first contact hole formed through the third insulator and the second conductor, the first contact hole reaching the second insulator; a third conductor formed in the first contact hole, wherein a side wall of the third conductor is electrically connected to a side wall of the second conductor; a second contact hole formed through the third insulator and the first insulator, the second contact hole reaching the first c

Abstract: A semiconductor device having a reduced bit line parasitic capacitance and a method of making same is presented. The semiconductor device includes a first, second, third, and fourth interlayer dielectric layers, first and second bit lines, first and second landing plug and first and second storage node contacts. An optional capacitor may be added to complete a CMOS configuration for the semiconductor device. The storage node contacts traverse through the interlayer dielectric layer and are electrically coupled to their respective landing plug contacts. The storage node contacts are deliberately offset, relative to the center of the corresponding landing plug contacts, at a predetermined distance in a direction away from the first bit line. This offsetting aids reducing the parasitic capacitance between the bit line and a storage node.

Abstract: There are provided a semiconductor device having a vertical transistor and a method of fabricating the same. The method includes preparing a semiconductor substrate having a cell region and a peripheral circuit region. Island-shaped vertical gate structures two-dimensionally aligned along a row direction and a column direction are formed on the substrate of the cell region. Each of the vertical gate structures includes a semiconductor pillar and a gate electrode surrounding a center portion of the semiconductor pillar. A bit line separation trench is formed inside the semiconductor substrate below a gap region between the vertical gate structures, and a peripheral circuit trench confining a peripheral circuit active region is formed inside the semiconductor substrate of the peripheral circuit region. The bit line separation trench is formed in parallel with the column direction of the vertical gate structures.

Abstract: The invention relates to a DRAM memory device with a capacity associated with a field effect transistor, in which all or some of the molecules capable of storing the loads comprising a polyoxometallate are incorporated into the capacity, or a flash-type memory using at least one field effect transistor, in which the molecules capable of storing the loads comprising a polyoxometallate are incorporated into the floating grid of the transistor. The invention also relates to a method for producing on such device and to an electronic appliance comprising one such memory device.

Abstract: An integrated circuit including a gate electrode is disclosed. One embodiment provides a transistor including a first source/drain electrode and a second source/drain electrode. A channel is arranged between the first and the second source/drain electrode in a semiconductor substrate. A gate electrode is arranged adjacent the channel layer and is electrically insulated from the channel layer. A semiconductor substrate electrode is provided on a rear side. The gate electrode encloses the channel layer at least two opposite sides.

Abstract: The semiconductor device includes a device isolation structure formed in a semiconductor substrate to define an active region, a bridge type channel structure formed in the active region, and a coaxial type gate electrode surrounding the bridge type channel structure of a gate region. The bridge type channel structure is separated from the semiconductor substrate thereunder by a predetermined distance in a vertical direction.

Abstract: Techniques for providing floating body memory devices are disclosed. In one particular exemplary embodiment, the techniques may be realized as a semiconductor device comprising a floating gate, a control gate disposed over the floating gate, a body region that is electrically floating, wherein the body region is configured so that material forming the body region is contained under at least one lateral boundary of the floating gate, and a source region and a drain region adjacent the body region.

Abstract: A method of forming a buried digit line is disclosed. Sacrificial spacers are formed along the sidewalls of an isolation trench, which is then filled with a sacrificial material. One spacer is masked while the other spacer is removed and an etch step into the substrate beneath the removed spacer forms an isolation window. Insulating liners are then formed along the sidewalls of the emptied trench, including into the isolation window. A digit line recess is then formed through the bottom of the trench between the insulating liners, which double as masks to self-align this etch. The digit line recess is then filled with metal and recessed back, with an optional prior insulating element deposited and recessed back in the bottom of the recess.

Abstract: A semiconductor device includes a semiconductor substrate, an element-isolating region formed in the semiconductor substrate, a real element region formed in the semiconductor substrate and outside the element-isolating region and having a metal silicide layer formed on the surface thereof, and a dummy element region formed in the semiconductor substrate and outside the element-isolating region and having a metal silicide layer formed on the surface thereof. The ratio of the sum of pattern areas of the real element region and dummy element region occupied in a 1 ?m-square range of interest including the element region is 25% or more.