Abstract: A charge-balance power device and a method of manufacturing the charge-balance power device are provided. The charge-balance power device includes: a charge-balance body region in which one or more first conductive type pillars as a first conductive type impurity region and one or more second conductive type pillars as a second conductive type impurity region are arranged; a first conductive type epitaxial layer that is formed on the charge-balance body region; and a transistor region that is formed in the first conductive type epitaxial layer. With this invention, it is possible to form the same charge-balance body region regardless of the structure of the transistor region formed on the top side of wafer.

Abstract: According to one embodiment, a semiconductor device includes a first semiconductor layer of a first conductivity type and a second semiconductor layer of a second conductivity type. The first semiconductor layer is formed with a trench. The second semiconductor layer is buried in the trench, and includes a hollow portion. A length of the hollow portion along depth direction of the trench is 5 ?m or less or 15 ?m or more.

Abstract: A method of forming an electrical device is provided that includes forming at least one semiconductor device on a first semiconductor layer of the SOI substrate. A handling structure is formed contacting the at least one semiconductor device and the first semiconductor layer. A second semiconductor layer and at least a portion of the dielectric layer of the SOI substrate are removed to provide a substantially exposed surface of the first semiconductor layer. A retrograded well may be formed by implanting dopant through the substantially exposed surface of the first semiconductor layer into a first thickness of the semiconductor layer that extends from the substantially exposed surface of the semiconductor layer, wherein a remaining thickness of the semiconductor layer is substantially free of the retrograded well dopant. The retrograded well may be laser annealed.

Abstract: A method of fabricating a semiconductor device with back side conductive plugs is provided here. The method begins by forming a gate structure overlying a semiconductor-on-insulator (SOI) substrate. The SOI substrate has a support layer, an insulating layer overlying the support layer, an active semiconductor region overlying the insulating layer, and an isolation region outboard of the active semiconductor region. A first section of the gate structure is formed overlying the isolation region and a second section of the gate structure is formed overlying the active semiconductor region. The method continues by forming source/drain regions in the active semiconductor region, and thereafter removing the support layer from the SOI substrate. Next, the method forms conductive plugs for the gate structure and the source/drain regions, where each of the conductive plugs passes through the insulating layer.

Abstract: A method of fabricating a semiconductor device with back side conductive plugs is provided here. The method begins by forming a gate structure overlying a semiconductor-on-insulator (SOI) substrate. The SOI substrate has a support layer, an insulating layer overlying the support layer, an active semiconductor region overlying the insulating layer, and an isolation region outboard of the active semiconductor region. A first section of the gate structure is formed overlying the isolation region and a second section of the gate structure is formed overlying the active semiconductor region. The method continues by forming source/drain regions in the active semiconductor region, and thereafter removing the support layer from the SOI substrate. Next, the method forms conductive plugs for the gate structure and the source/drain regions, where each of the conductive plugs passes through the insulating layer.

Abstract: A CMOS FinFET semiconductor device provides an NMOS FinFET device that includes a compressive stress metal gate layer over semiconductor fins and a PMOS FinFET device that includes a tensile stress metal gate layer over semiconductor fins. A process for forming the same includes a selective annealing process that selectively converts a compressive metal gate film formed over the PMOS device to the tensile stress metal gate film.

Abstract: A method of forming a field effect transistor includes forming trench isolation material within a semiconductor substrate and on opposing sides of a semiconductor material channel region along a length of the channel region. The trench isolation material is formed to comprise opposing insulative projections extending toward one another partially under the channel region along the channel length and with semiconductor material being received over the projections. The trench isolation material is etched to expose opposing sides of the semiconductor material along the channel length. The exposed opposing sides of the semiconductor material are etched along the channel length to form a channel fin projecting upwardly relative to the projections. A gate is formed over a top and opposing sides of the fin along the channel length. Other methods and structures are disclosed.

Abstract: The invention provides various embodiments of a memory cell formed on a semiconductor-on-insulator (SeOI) substrate and comprising one or more FET transistors. Each FET transistor has a source region and a drain region at least portions of which are arranged in the thin layer of the SeOI substrate, a channel region in which a trench is made, and a gate region formed in the trench. Specifically, the source, drain and channel regions also have portions which are arranged also beneath the insulating layer of the SeOI substrate; the portion of channel region beneath the insulating layer extends between the portions of the source and drain regions also beneath the insulating layer; and the trench in the channel region extends into the depth of the base substrate beyond the insulating layer. Also, methods for fabricating such memory cells and memory arrays including a plurality of such memory cells.

Abstract: A device and method is provided that in one embodiment provides a first semiconductor device including a first gate structure on a first channel region, in which a first source region and a first drain region are present on opposing sides of the first channel region, in which a metal nitride spacer is present on only one side of the first channel region. The device further includes a second semiconductor device including a second gate structure on a second channel region, in which a second source region and a second drain region are present on opposing sides of the second channel region. Interconnects may be present providing electrical communication between the first semiconductor device and the second semiconductor device, in which at least one of the first semiconductor device and the second semiconductor device is inverted. A structure having a reverse halo dopant profile is also provided.

Abstract: An electrical device is provided that in one embodiment includes a semiconductor-on-insulator (SOI) substrate having a semiconductor layer with a thickness of less than 10 nm. A semiconductor device having a raised source region and a raised drain region of a single crystal semiconductor material of a first conductivity is present on a first surface of the semiconductor layer. A resistor composed of the single crystal semiconductor material of the first conductivity is present on a second surface of the semiconductor layer. A method of forming the aforementioned electrical device is also provided.

Abstract: The invention relates to a semiconductor device produced on a semiconductor-on-insulator substrate that includes a thin layer of semiconductor material separated from a base substrate by a buried insulating layer, the device including a first conducting region in the thin layer, a second conducting region in the base substrate and a contact connecting the first region to the second region through the insulating layer. The invention also relates to a process for fabricating such semiconductor devices.

Abstract: A semiconductor device includes an input/output pad, and a data transfer unit configured to form a parasitic diode between the input/output pad and a power supply terminal thereof to discharge an introduced electrostatic discharge (ESD), and form a data transfer path between the input/output pad and an internal circuit in response to a control signal.

Abstract: The present invention mainly provides an ESD protective element which can be built in high voltage semiconductor integrated circuit devices without increasing the chip area. An ESD protective element according to one embodiment has a construction comprising a semiconductor layer, a first region of a first conduction type formed in the semiconductor layer, a first region of a second conduction type formed in the semiconductor layer away from the first region of the first conduction type, a second region of the second conduction type formed in the first region of the second conduction type and has a higher impurity concentration than it, and a second region of the first conduction type formed in the second region of the second conduction type and has a high impurity concentration. The first and second regions of the second conduction type are in an electrically floating state.

Abstract: The present disclosure provides ESD protection devices that can effectively cope with electrostatic stress of microchips for high voltage operation. The ESD protection device is a double diffused drain N-type MOSFET (DDDNMOS) ESD protection device, in which a gate, a source region and a well-pickup region are connected to a ground terminal and a drain region is connected to a power terminal or individual input/output terminals.

Abstract: A high-frequency power amplifier of the type to be mounted in an RF module for mobile phones having high-frequency power field effect transistors and gate protective diodes which are coupled between the gates and the sources of the high-frequency power field effect transistors. The gate protective diodes have an n type region formed over the main surface of a p type epitaxial layer, a first p type region formed at the center of the main surface of the n type region, a second p type region formed over the main surface of the epitaxial layer around the n type region from the periphery of the main surface of the n type region, and p+ type buried layers for coupling the second p type region to a substrate body. The distance between the end portions of the p+ type buried layers and the n+ type region is 7 ?m or more.

Abstract: A structure of a strained-silicon transistor includes a PMOS disposed on a substrate, a silicon nitride layer positioned on the PMOS, and a compressive stress film disposed on the silicon nitride layer, wherein the silicon nitride has a stress between ?0.1 Gpa and ?3.2 Gpa, and the stress of the silicon nitride is smaller than the stress of the compressive stress layer.

Abstract: An integrated circuit structure includes a substrate and at least one pair of complementary transistors on or in the substrate. The pair of complementary transistors comprises a first transistor and a second transistor. The structure also includes a first stress-producing layer on the first transistor and the second transistor, and a second stress-producing layer on the first stress-producing layer over the first transistor and the second transistor. The first stress-producing layer applies tensile strain force on the first transistor and the second transistor. The second stress-producing layer applies compressive strain force on the first stress-producing layer, the first transistor, and the second transistor.

Abstract: There is provided a CMOSFET device with a threshold voltage controlled by means of its gate stack configuration and a method of fabricating the same. The CMOSFET device comprises: a semiconductor substrate; an interface layer grown on the silicon substrate; a first high-k gate dielectric layer deposited on the interface layer; a very thin metal layer deposited on the first high-k gate dielectric layer; a second high-k gate dielectric layer deposited on the metal layer; and a gate electrode layer deposited on the second high-k gate dielectric layer. According to to the present invention, the very thin metal layers are deposited between the high-k gate dielectric layers for NMOS and PMOS devices respectively, such that a flat band voltage of the device is adjusted by means of positive or negative charges generated by the metal layers inside the high-k gate dielectric layers, and thus the threshold voltage of the device is controlled.

Abstract: A semiconductor device includes: a cooling function component including an active region made of an impurity region and formed on a surface of a semiconductor layer, an N-type gate made of a semiconductor including an N-type impurity, a P-type gate made of a semiconductor including a P-type impurity, a first metal wiring connected to the N-type gate, the P-type gate and the active region, a second metal wiring connected to the P-type gate and the N-type gate, and a heat releasing portion connected to the second metal wiring for releasing heat to the outside.

Abstract: A cell includes a plurality of diffusion region pairs, each of the diffusion region pairs being formed by a first impurity diffusion region which is a constituent of a transistor and a second impurity diffusion region such that the first and second impurity diffusion regions are provided side-by-side in a gate length direction with a device isolation region interposed therebetween. In each of the diffusion region pairs, the first and second impurity diffusion regions have an equal length in the gate width direction and are provided at equal positions in the gate width direction, and a first isolation region portion, which is part of the device isolation region between the first and second impurity diffusion regions, has a constant separation length. In the diffusion region pairs, the first isolation region portions have an equal separation length.

Abstract: A semiconductor device includes: a first MIS transistor of a first conductivity type having a first active region as a region of a semiconductor substrate surrounded by an element isolation region formed in an upper portion of the semiconductor substrate, a first gate insulating film having a first high dielectric film formed on the first active region, and a first gate electrode formed on the first gate insulating film; and a resistance element having a second high dielectric film formed on the element isolation region and a resistance layer made of silicon formed on the second high dielectric film. The first high dielectric film and the second high dielectric film include the same high dielectric material, and the first high dielectric film includes a first adjustment metal, but the second high dielectric film does not include the first adjustment metal.

Abstract: A Fin FET whose fin (12) has an upper portion (30) doped with a first conductivity type and a lower portion (32) doped with a second conductivity type, wherein the junction (34) between the upper portion (30) and the lower portion (32) acts as a diode; and the FinFET further comprises: at least one layer (26, 28) of high-k dielectric material (for example Si3N4) adjacent at least one side of the fin (12) for redistributing a potential drop more evenly over the diode, compared to if the at least one layer of high-k dielectric material were not present, when the upper portion (30) is connected to a first potential and the lower portion (32) is connected to a second potential thereby providing the potential drop across the junction (34). Examples of the k value for the high-k dielectric material are k?5, k?7.5, and k?20.

Abstract: The electrical characteristics of a semiconductor device are enhanced. In the package of the semiconductor device, there are encapsulated first and second semiconductor chips with a power MOS-FET formed therein and a third semiconductor chip with a control circuit for controlling their operation formed therein. The bonding pads for source electrode of the first semiconductor chip on the high side are electrically connected to a die pad through a metal plate. The bonding pad for source electrode of the second semiconductor chip on the low side is electrically connected to lead wiring through a metal plate. The metal plate includes a first portion in contact with the bonding pad of the second semiconductor chip, a second portion extended from a short side of the first portion to the lead wiring, and a third portion extended from a long side of the first portion to the lead wiring.

Abstract: N-channel power semiconductor devices in which an insulated field plate is coupled to the drift region, and immobile electrostatic charge is also present at the interface between the drift region and the insulation around the field plate. The electrostatic charge permits OFF-state voltage drop to occur near the source region, in addition to the voltage drop which occurs near the drain region (due to the presence of the field plate).

Abstract: The present disclosure provides methods and apparatus of fluorine passivation in IC device fabrication. In one embodiment, a method of fabricating a semiconductor device includes providing a substrate and passivating a surface of the substrate with a mixture of hydrofluoric acid and alcohol to form a fluorine-passivated surface. The method further includes forming a gate dielectric layer over the fluorine-passivated surface, and then forming a metal gate electrode over the gate dielectric layer. A semiconductor device fabricated by such a method is also disclosed.

Abstract: A method of manufacturing a semiconductor device includes forming a polysilicon pattern, source/drain, and side-wall spacer, epitaxially growing silicide films on the source/drain, epitaxially growing silicon films selectively on the silicide film, removing the polysilicon pattern, forming a gate insulating film and gate electrode.

Abstract: A micro electronic mechanical system structure and a manufacturing method thereof are provided. A substrate has a plurality of conductive regions is provided. A dielectric layer is formed on the substrate. A plurality of openings and recesses are formed in the dielectric layer, wherein the openings expose the conductive regions. The recesses are located between the openings. A conductive layer is formed on the dielectric layer and the openings and the recesses are filled with the conductive layer. The conductive layer is patterned to form a plurality of strips of the first conductive patterns on the dielectric layer and a second conductive pattern on the sidewall and the bottom of each recess, wherein the first conductive patterns are connected with each other through the second conductive patterns. The dielectric layer is removed. The second conductive patterns between the first conductive patterns are removed.

Abstract: A process for manufacturing a component is described. In a first manufacturing step a base structure having a substrate, a diaphragm, and a cavern region is provided. The diaphragm is oriented substantially parallel to a main plane of extension of the substrate. The cavern region is situated between the substrate and the diaphragm, and has an access opening. In a second manufacturing step, a first conductive layer is provided at least partially in the cavern region, in particular on a second side of the diaphragm facing the substrate, perpendicularly to the main plane of extension.

Abstract: Hot-melt sealing glass compositions that include one or more glass frits dispersed in a polymeric binder system. The polymeric binder system is a solid at room temperature, but melts at a temperature of from about 35° C. to about 90° C., thereby forming a flowable liquid dispersion that can be applied to a substrate (e.g., a cap wafer and/or a device wafer of a MEMS device) by screen printing. Hot-melt sealing glass compositions according to the invention rapidly re-solidify and adhere to the substrate after being deposited by screen printing. Thus, they do not tend to spread out as much as conventional solvent-based glass frit bonding pastes after screen printing. And, because hot-melt sealing glass compositions according to the invention are not solvent-based systems, they do not need to be force dried after deposition.

Abstract: The invention relates to a capacitive sensor device 100. The capacitive sensor device (100) comprises a substrate (401), a first electrode (101) coupled to the substrate (401, a second electrode (102) coupled to the substrate (401) and a movable element (103). The movable element (103) is capacitively coupled to the first electrode (101), the moveable element (103) and the first electrode (101) representing a first capacitor (104). The movable element (103) is capacitively coupled to the second electrode (102), the moveable element (103) and the second electrode (102) representing a second capacitor (105). The movable element (103) is movable between the first electrode (101) and the second electrode (102) in such a manner, that an electrical impedance between the first electrode (101) and the second electrode (102) is changeable due to a change of a position of the movable element (103). The movable element (103) is decoupled from the substrate (401), in particular to a signal line.

Abstract: A microelectromechanical system (MEMS) diaphragm is provided. The MEMS diaphragm includes a first conductive layer, a second conductive layer and a first dielectric layer. The first conductive layer is disposed on a substrate and having a plurality of openings. The openings having a first dimension and the openings having a second dimension are arranged alternately, and the first dimension is not equal to the second dimension. The second conductive layer is disposed between the first conductive layer and the substrate. The first dielectric layer is partially disposed between the first conductive layer and the second conductive layer, so that a portion of the first conductive layer is suspended.

Abstract: A magnetic tunnel junction stack that includes a pinned magnetic layer, a tunnel barrier layer formed of magnesium oxide (MgO), and a free magnetic layer formed adjacent to the tunnel barrier layer and of a material having a magnetization perpendicular to an MgO interface of the tunnel barrier layer and with a magnetic moment per unit area within a factor of 2 of approximately 2 nanometers (nm)×300 electromagnetic units per cubic centimeter (emu/cm3).

Abstract: A magnetic tunnel junction (MTJ) storage element and method of forming the MTJ are disclosed. The magnetic tunnel junction (MTJ) storage element includes a pinned layer, a barrier layer, a free layer and a composite hardmask or top electrode. The composite hardmask/top electrode architecture is configured to provide a non-uniform current path through the MTJ storage element and is formed from electrodes having different resistance characteristics coupled in parallel. An optional tuning layer interposed between the free layer and the top electrode helps to reduce the damping constant of the free layer.

Abstract: The present invention makes it possible to obtain: a semiconductor device capable of forming a highly reliable upper wire without a harmful influence on the properties of the magnetic material for an MTJ device; and the manufacturing method thereof. Plasma treatment is applied with reducible NH3 or H2 as pretreatment. Thereafter, a tensile stress silicon nitride film to impose tensile stress on an MTJ device is formed over a clad layer and over an interlayer dielectric film where the clad layer is not formed. Successively, a compressive stress silicon nitride film to impose compressive stress on the MTJ device is formed over the tensile stress silicon nitride film. The conditions for forming the tensile stress silicon nitride film and the compressive stress silicon nitride film are as follows: a parallel plate type plasma CVD apparatus is used; the RF power is set in the range of 0.03 to 0.4 W/cm2; and the film forming temperature is set in the range of 200° C. to 350° C.

Abstract: Electronic devices that include (i) a magnetization controlling structure; (ii) a tunnel barrier structure; and (iii) a magnetization controllable structure including: a first polarizing layer; and a first stabilizing layer, wherein the tunnel barrier structure is between the magnetization controlling structure and the magnetization controlling structure and the first polarizing layer is between the first stabilizing layer and the tunnel barrier structure, wherein the electronic device has two stable overall magnetic configurations, and wherein a first unipolar current applied to the electronic device will cause the orientation of the magnetization controlling structure to reverse its orientation and a second unipolar current applied to the electronic device will cause the magnetization controllable structure to switch its magnetization in order to obtain one of the two stable overall magnetic configurations, wherein the second unipolar current has an amplitude that is less than the first unipolar current.

Abstract: A semiconductor package includes a package body with a cavity housing a first integrated circuit die. A wireless tag including a wireless element and an antenna is embedded in the semiconductor package. In one embodiment, the antenna is embedded in the package body of the semiconductor package. In another embodiment, the antenna is formed on or in the first integrated circuit die housed in the semiconductor package. According to another aspect of the present invention, the semiconductor package may be mounted on a printed circuit board and a second antenna is formed on the printed circuit board in electrical connection to the antenna embedded in the semiconductor package.

Abstract: The invention discloses a process for manufacturing a radiation detector for detecting e.g. 200 eV electrons. This makes the detector suited for e.g. use in an Scanning Electron Microscope. The detector is a PIN photodiode with a thin layer of pure boron connected to the p+-diffusion layer. The boron layer is connected to an electrode with an aluminium grid to form a path of low electrical resistance between each given point of the boron layer and the electrode. The invention addresses forming the aluminium grid on the boron layer without damaging the boron layer.

Abstract: An avalanche photodiode detector is provided with a substrate including an array of avalanche photodiodes. An optical interface surface of the substrate is arranged for accepting external input radiation. There is provided at least one cross-talk blocking layer of material including apertures positioned to allow external input radiation to reach photodiodes and including material regions positioned for attenuating radiation in the substrate that is produced by photodiodes in the array. Alternatively at least one cross-talk blocking layer of material is disposed on the optical interface surface of the substrate to allow external input radiation to reach photodiodes and attenuate radiation in the substrate that is produced by photodiodes in the array. At least one cross-talk filter layer of material can be disposed in the substrate adjacent to the photodiode structures, including a material that absorbs radiation in the substrate that is produced by photodiodes in the array.

Abstract: The present invention is has an object of providing an optical device miniaturized while maintaining bonding strength between a semiconductor substrate and a light-transmissive plate, reducing possibility of warpage, and maintaining yields and design flexibility, a method of manufacturing the optical device, and an electronic apparatus. The optical device according to the present invention includes a semiconductor substrate having one surface in which a light-receiving element is formed; and a light-transmissive plate provided above the semiconductor substrate so as to cover the light-receiving element. The semiconductor substrate and the light-transmissive plate are partially bonded above a light-receiving unit of the semiconductor substrate. The light-receiving element is formed in the light-receiving unit.

Abstract: Embodiments of the invention provide for fabricating a filter, for electromagnetic radiation, in at least three ways, including (1) fabricating integrated thin film filters directly on a detector; (2) fabricating a free standing thin film filter that may be used with a detector; and (3) treating an existing filter to improve the filter's properties.

Abstract: Disclosed is an integrated circuit (100) comprising a substrate (110) carrying a plurality of light-sensitive elements (112) and a blazed grating (120) comprising a plurality of diffractive elements (122) for diffracting respective spectral components (123-125) of incident light (150) to respective light-sensitive elements (112), the blazed grating (120) comprising a stack of layers, at least some of these layers comprising first portions, e.g. metal portions (202, 222, 242) arranged such that each diffractive element (122) comprises a stepped profile of stacked first portions with a first portion in a higher layer laterally extending beyond a first portion in a lower layer of said stepped profile.

Abstract: The present invention is directed toward a detector structure, detector arrays, and a method of detecting incident radiation. The present invention comprises several embodiments that provide for reduced radiation damage susceptibility, decreased affects of crosstalk, reduced dark current (current leakage) and increased flexibility in application. In one embodiment, a photodiode array comprises a substrate having at least a front side and a back side, a plurality of diode elements integrally formed in the substrate forming the array, wherein each diode element has a p+ fishbone pattern on the front side, and wherein the p+ fishbone pattern substantially reduces capacitance and crosstalk between adjacent photodiodes, a plurality of front surface cathode and anode contacts, and wire interconnects between diode elements made through a plurality of back surface contacts.

Abstract: Present embodiments relate to a semiconductor device having a backside redistribution layer and a method for forming such a layer. Specifically, one embodiment includes providing a substrate comprising a via formed therein. The substrate has a front side and a backside. The embodiment may further include forming a trench on the backside of the substrate, disposing an insulating material in the trench, and forming a trace over the insulating material in the trench.

Abstract: Provided is a barium titanate-based semiconductor ceramic composition which contains no Pb, which can have an increased Curie temperature, which exhibits slight deterioration with time, and which has high reliability, containing a barium titanate-based semiconductor ceramic represented by the composition formula (Ba1-x-y-zSry(A1Bi)xA2z)TiO3, where A1 is an alkali metal element, A2 is a rare-earth element, 0.03?x?0.20, 0.02?y?0.20, and 0.0005?z?0.015, and x?0.10?y?(5/4)·x. In addition, 0.01 to 0.20 molar parts of Mn per 100 molar parts of Ti is preferably added thereto.

Abstract: An electrical device in which an interface layer is disposed between and in contact with a metal and a Si-based semiconductor, the interface layer being of a thickness effective to depin of the Fermi level of the semiconductor while still permitting current to flow between the metal and the semiconductor. The interface layer may include a layer of a passivating material (e.g., made from nitrogen, oxygen, oxynitride, arsenic, hydrogen and/or fluorine) and sometimes also includes a separation layer. In some cases, the interface layer may be a monolayer of a semiconductor passivating material. The interface layer thickness corresponds to a minimum specific contact resistance of less than or equal to 10 ?-?m2 or even less than or equal to 1 ?-?m2 for the electrical device.

Abstract: A method is described for creating at least one recess in a semiconductor component, in particular a micromechanical or electrical semiconductor component, having the following steps: applying at least one mask to the semiconductor component, forming at least one lattice having at least one or more lattice openings in the mask over the recess to be formed, the lattice opening or lattice openings being formed as a function of the etching rate and/or the dimensioning of the recess to be formed; forming the recess below the lattice.

Abstract: A nonvolatile memory cell including a storage element in series with a diode steering element. At least one interface of the diode steering element is passivated.

Abstract: A design structure is provided for interconnect structures containing various capping materials for electrical fuses and other related applications. The structure includes a first interconnect structure having a first interfacial structure and a second interconnect structure adjacent to the first structure. The second interconnect structure has second interfacial structure different from the first interfacial structure.

Abstract: In order to improve the reliability of a semiconductor device having a fuse formed by a Damascene technique, a barrier insulating film and an inter-layer insulating film are deposited over a fourth-layer wiring and a fuse. The barrier insulating film is an insulating film for preventing the diffusion of Cu and composed of a SiCN film deposited by plasma CVD like the underlying barrier insulating film. The thickness of the barrier insulating film covering the fuse is larger than the thickness of the underlying barrier insulating film so as to improve the moisture resistance of the fuse.

Abstract: Disclosed are embodiments of a circuit and method for electroplating a feature (e.g., a BEOL anti-fuse device) onto a wafer. The embodiments eliminate the use of a seed layer and, thereby, minimize subsequent processing steps (e.g., etching or chemical mechanical polishing (CMP)). Specifically, the embodiments allow for selective electroplating metal or alloy materials onto an exposed portion of a metal layer in a trench on the front side of a substrate. This is accomplished by providing a unique wafer structure that allows a current path to be established from a power supply through a back side contact and in-substrate electrical connector to the metal layer. During electrodeposition, current flow through the current path can be selectively controlled. Additionally, if the electroplated feature is an anti-fuse device, current flow through this current path can also be selectively controlled in order to program the anti-fuse device.