Abstract: Methods and apparatus are provided for measuring contaminant mobile ions in a dielectric portion of a semiconductor. The apparatus is comprised of a heat source configured to elevate a temperature of the dielectric portion of the semiconductor and mobilize the contaminant mobile ions. The apparatus is also comprised of a fluid source configured to expose the dielectric portion of the semiconductor to a mobilizing fluid having contaminant ion releasing atoms that assists in mobilizing the contaminant mobile ions. The apparatus further comprises a mobile ion measurement unit configured to perform measurements of the contaminant mobile ions in the dielectric portion of the semiconductor.

Abstract: The present invention provides a novel method for increasing the amount of deuterium incorporated into trap sites of a transistor device during a deuterium passivation anneal by electrically pre-stressing the fabricated device prior to a deuterium anneal. The method of the present invention equally applies to SOI and CMOS technology. As a result, the incorporation of more deuterium during a deuterium anneal in the process flow reduces the number of undesirable trap sites.

Abstract: The present invention is generally directed to various methods of using ion implantation techniques to control various metal formation processes. In one illustrative embodiment, the method comprises forming a metal seed layer above a patterned layer of insulating material, the patterned layer of insulating material defining a plurality of field areas, deactivating at least a portion of the metal seed layer in areas where the metal seed layer is positioned above at least some of the field areas, and performing a deposition process to deposit a metal layer above the metal seed layer. In some embodiments, the metal may be comprised of copper, platinum, nickel, tantalum, tungsten, cobalt, etc. Portions of the metal seed layer may be deactivated by implanting ions into portions of the metal seed layer positioned above at least some of the field areas. The implanted ions may be comprised of nitrogen, carbon, silicon, hydrogen, etc.

Abstract: A method and apparatus for a mixed-mode operation of an electrostatic chuck in a semiconductor substrate processing system. The chuck is operated in a voltage mode before and after a processing and is operated in a current mode during the processing to suppress arcing during the processing of a substrate.

Abstract: A method in which a recess is formed in the surface of a semiconductor substrate and a material is grown on the inner wall of the recess, includes the steps of producing an electrically insulating layer on the surface of the substrate outside the recess, and selectively growing the material on the inner wall of the recess as a result of the substrate, as an electrode, being brought into contact with an electrolysis liquid and electrolysis being carried out, during which the insulating layer prevents the material from growing outside the recess. Before the electrolysis is carried out, a reserve material is epitaxially deposited on the inner wall of the recess and, during the electrolysis, the reserve material is converted into the material being grown by electrolysis.

Abstract: A method comprising forming a sacrificial layer over less than the entire portion of a contact area on a substrate, the sacrificial layer having a thickness defining an edge over the contact area, forming a spacer layer over the spacer, the spacer layer conforming to the shape of the first sacrificial layer such that the spacer layer comprises an edge portion over the contact area adjacent the first sacrificial layer edge, removing the sacrificial layer, while retaining the edge portion of the spacer layer over the contact area, forming a dielectric layer over the contact area, removing the edge portion, and forming a programmable material to the contact area formerly occupied by the edge portion.

Abstract: A method for etching a metal layer on a scale of nano meters, includes preparing a substrate on which a metal layer is formed, positioning a micro tip over the metal layer, generating an electron beam from the micro tip by applying a predetermined voltage between the metal layer and the micro tip, and etching the surface of the metal layer into a predetermined pattern with the electron beam. Accordingly, it is possible to form an etched pattern by applying a negative bias to a micro tip without applying a strong mechanical force to the micro tip, and heating/melting the metal layer with the use of an electron beam emitted from the micro tip which is negative-biased.

Abstract: A method for producing a dielectric layer on a substrate made of a conductive substrate material includes reducing a leakage current that flows through defects of the dielectric layer at least by a self-aligning and self-limiting electrochemical conversion of the conductive substrate material into a nonconductive substrate follow-up material in sections of the substrate that are adjacent to the defects. Also provided is a configuration including a dielectric layer with defects, a substrate made of a conductive substrate material, and reinforcement regions made of the nonconductive substrate follow-up material in sections adjacent to the defects.

Abstract: Floating-gate field-effect transistors or memory cells formed in isolated wells are useful in the fabrication of non-volatile memory arrays and devices. A column of such floating-gate memory cells are associated with a well containing the source/drain regions for each memory cell in the column. These wells are isolated from source/drain regions of other columns of the array. Fowler-Nordheim tunneling can be used to program and erase such floating-gate memory cells either on an individual basis or on a bulk or block basis.

Abstract: A metal silicide fuse for a semiconductor device. The fuse includes a conductive region positioned adjacent a common well of a first conductivity type, a terminal region positioned adjacent a well of a second conductivity type, and a narrowed region located between the terminal region and the conductive region and positioned adjacent a boundary between the two wells. Upon applying at least a programming current to the fuse, the fuse “blows” at the narrowed region. The diode or diodes between wells of different conductivity types wells and the Schottky diode or diodes between the remaining portions of the fuse and wells adjacent thereto control the flow of current through the remainder of the fuse and through the associated wells of the semiconductor device. When the fuse has been “blown,” the diodes and Schottky diodes prevent current of a normal operating voltage from flowing through the wells of the semiconductor device.

Abstract: In one illustrative embodiment, the method comprises providing an SOI substrate comprised of an active layer, a buried insulation layer and a bulk substrate, the active layer being doped with a first type of dopant material, the bulk substrate having an inner well formed therein adjacent a surface of the bulk substrate and under the active layer, the inner well being doped with the first type of dopant material, forming a transistor above the SOI substrate in an area above the inner well and applying a voltage to the inner well to vary a threshold voltage of the transistor. In some embodiments, the method further comprises forming an NMOS transistor, wherein the active layer and the inner well are doped with a P-type dopant material. In other embodiments, the method further comprises forming a PMOS transistor, wherein the active layer and the inner well are doped with an N-type dopant material.

Abstract: A multiplicity of components form a photodiode array on a substrate. Each of the components consists of a transistor of the p-n-p type with the outermost p-doped layer being transformed into an optical filter by control of the anodic etching operation utilizing transistor characteristics of the respective transistor. The result can provide red, blue and green filters in a color camera.

Abstract: A structure having projections is provided. The structure having projections comprises a first projection formed on a first layer containing a first material, and a plurality of second projections formed around the first projection and containing a material capable of being subjected to anodic oxidation.

Abstract: A method for electrically determining in a semiconductor wafer the location of edges of a well that underlies an insulating layer that includes forming in the wafer before forming of the well and the insulating layer a plurality of conductive stripes will that pass under the future insulating layer and extend to varying distances under the insulating layer so as to include stripes that will penetrate an edge to be located so as to form a low resistance connection thereto and stripes that will fall short of an edge to be located. From the stripes of minimum penetration that make low resistance can be determined the location of the well edges.

Abstract: An epitaxial growth layer, an oxide film, and a passivation film are formed on a silicon substrate. Except for an opening formed on a part of the passivation film, the upper surface of the passivation film is covered with a metal protective film made of tungsten (W). With the silicon substrate immersed in a high-concentration hydrofluoric aqueous solution, anodization is performed with the silicon substrate as an anode and the metal protective film as a counter electrode.

Abstract: Metal-insulator-metal capacitor structures are formed in semiconductor substrates using an anodization procedure on deposited underlying metalization followed by deposition of the second metal and planarization by chemical-mechanical polishing or other procedures. The process is additive in character, as opposed to traditional subtractive etch processes for forming capacitor structures. In addition, the process can be used in damascene applications, and can be used to form a wide variety of capacitive structures while reducing the number of mask layers required for formation.

Abstract: The semiconductor device includes a semiconductor substrate, an insulating layer on the semiconductor substrate wherein a groove is patterned to a predetermined depth in an upper surface of the insulating layer, a fuse layer at sidewalls and on a bottom of the groove, and a wire connected electrically to the fuse layer.

Abstract: A method of field-assisted fusion bonding produces multiple-layer devices. Contacts (301, 303, 305, 307, 309) are placed at various points along different surfaces of a combination of two or more wafers (201, 203, 205, 501, 503, 505, 801, 803). An electric field is applied to the contacts (301, 303, 305, 307, 309), thereby creating an electrostatic attractive force between the wafers (201, 203, 205, 501, 503, 505, 801, 803). The temperature of the wafer combination is elevated to a fusion bonding temperature while the electric field is applied.

Abstract: A method for fabricating a thin film transistor includes forming a buffer layer on a substrate, forming a first amorphous silicon layer on the buffer layer, forming a plurality of metal clusters on the first amorphous silicon layer, forming a second amorphous silicon layer on the metal clusters including the first amorphous silicon layer, and simultaneously applying a heat-treatment and an electrical field to crystallize the first and the second amorphous silicon layers.

Abstract: A photoresist is provided with an opening as a dummy pattern in a space area, i.e., a dummy region, other than a pattern of elements and circuits in one chip, thereby increasing the number of openings in the photoresist and performing ion implantation. This reduces the number of ions entering into the photoresist. As a result, the area in which the photoresist hardens due to the entering ions can be reduced, resulting in improved removability of the photoresist. The occurrence of charge-up can also be reduced. With a reduction in the area of regions other than the openings in the photoresist, a location where strong surface tension is generated can hardly be present. This allows the dimensional accuracy of the photoresist to be improved without making the photoresist thin in film thickness.

Abstract: Systems and methods are described for synthesis of films, coatings or layers using electrostatic fields. A method includes applying an electrostatic field across a first precursor layer that is coupled to a first substrate and a second precursor layer that is coupled to a second substrate; forming a composition layer; and moving the first substrate relative to the second substrate, wherein the composition layer remains coupled to the second substrate.

Abstract: A method for fabricating a thin film transistor. An active layer is first formed on a substrate, then a first insulating layer is formed on the active layer. Next, a gate electrode pattern is formed on the first insulating layer and an LDD region is formed by lightly doping ions in the active layer using the gate electrode pattern as a mask. A polymer layer is formed on a surface of the gate electrode pattern using an electrochemical polymerizing process, and source and drain contact layers are formed by densely doping ions in the active layer using the gate electrode pattern deposited with the polymer layer. A second insulating layer is then formed on a surface of the first insulating layer while covering the gate electrode pattern. Contact holes are formed through the insulating layers, and metal material is sputtered in the contact holes to form the source and drain electrodes.

Abstract: The present invention relates to a method for reducing low-frequency noise in a cooled circuit wherein low-frequency noise in a cryogenic semiconductor device is reduced by carrying out thermal cure. The semiconductor device is turned on at a first temperature, and the temperature of the semiconductor device is temporarily raised, while flowing current in the semiconductor device, to a second temperature that is higher than the first temperature, and then cooling the temperature of the semiconductor device from the second temperature to a cryogenic temperature, at which the semiconductor device can operate.

Abstract: A method of forming a low-temperature polysilicon, comprising steps of: providing a substrate with a surface on which a buffer layer, an amorphous silicon layer and a metal silicide layer are sequentially formed; forming a plurality of metal pads on predetermined regions of the metal silicide layer; and providing a current on the metal pads to transform the amorphous silicon layer into a polysilicon layer.

Abstract: A method for operating a P-channel SONOS memory device that has a charge trapping layer located on a substrate, a gate electrode located on the trapping layer, two doped regions located in the substrate at each side of the charge trapping layer. The two doped regions are set to be a drain region and a source region. When a programming action is intended, the gate electrode and the drain region are applied with a first negative high-level bias, and the source region and the substrate are applied with a grounded voltage. When an erasing action is intended, the gate electrode is a second negative bias which is smaller than the first negative voltage in absolute value. In the mean time, the drain region is applied with the third negative bias and the substrate is applied with a grounded voltage. The third negative voltage is larger than the second negative bias in absolute value.

Abstract: In a process for the electrochemical oxidation of a semiconductor substrate that has recesses, such as for example, capacitor trenches or mesopores, formed in a silicon surface region, self-limited oxide formation takes place. The end of this formation is reached as a function of the process parameters such as the doping of the silicon region, the applied voltage and the composition of the electrolyte used, as soon as either a predetermined maximum layer thickness of the formed oxide or a predetermined minimum residual silicon layer thickness between two adjacent recesses is reached. The self-limiting is achieved either as a result of the overall voltage applied over the silicon oxide layer, which has already formed, dropping or as a result of the space charge regions of adjacent recesses coming into contact with one another.

Abstract: The present invention offers an alternative method of tuning a meander line antenna. A layer of PN semiconductor material is inserted between a ground plane and a base element. A dc voltage is applied between the ground plane and the base element. A change in capacitance between the ground plane and the base element is effected. The impedance of the base element is thus changed, resulting in a change in the delay through the meander line tuning module as the propagation constant. This change in delay tunes the meander line antenna in the same manner as discrete switch elements by adjusting only a single voltage.

Abstract: A method of electrochemically etching a device, including forming a semiconductor substrate having a p-type semiconductor region on an n-type semiconductor region. A discrete semiconductor region is formed on the p-type semiconductor region and is isolated from the n-type semiconductor region. The n-type semiconductor region is exposed to an electrolyte with an electrical bias applied between the n-type semiconductor region and the electrolyte. The n-type semiconductor region is also exposed to radiation having energy sufficient to excite electron-hole pairs. In addition, a p-n junction reverse bias is applied between the p-type semiconductor region and the n-type semiconductor region to prevent the p-type semiconductor region and the discrete semiconductor region from etching while portions of the n-type semiconductor region exposed to the electrolyte and the radiation are etched.

Abstract: The present invention relates to a PIN photo diode, whish shows both high sensitivity and superior high frequency performance by the reduction of the dark current and the intrinsic capacitance. The PIN diode comprises a substrate made of InP, n-type layer made of InGaAs doped with Si, i-type layer made of GaInAs with unintentionally doped, and the p-type layer made of GaInAs doped with Zn, respective layers are sequentially grown and formed to a mesa structure by conventional technique. A passivation layer of InP covers the p-type layer and the i-type layer. The thickness h2 of a center region of the p-type layer is thinner than the thickness h1 of other region surrounding the center. By the configuration, the reduction of the dark current, the enhancing of the high frequency performance by the reduction of the intrinsic capacitance, and the improvement of the sensitivity by the decreasing the absorption in the p-type layer are achieved.

Abstract: The present invention creates an operating method for a semiconductor component having a substrate; having a conductive polysilicon strip which is applied to the substrate; having a first and a second electrical contact which are connected to the conductive polysilicon strip such that this forms an electrical resistance in between them; with the semiconductor component being operated reversibly in a current/voltage range in which it has a first differential resistance (Rdiff1) up to a current limit value (It) corresponding to an upper voltage limit value (Vt) and, at current values greater than this, has a second differential resistance (Rdiff2), which is less than the first differential resistance (Rdiff1).

Abstract: A method for crystallizing an amorphous film by doping phosphorus and using FE-MIC, and method for fabrication an LCD by using the same. The method for crystallizing an amorphous film includes forming an amorphous film containing an impurity on a substrate, forming a metal layer on the amorphous film, heat treating the amorphous film, and applying an electric field to the amorphous film.

Abstract: A method comprising forming a sacrificial layer over less than the entire portion of a contact area on a substrate, the sacrificial layer having a thickness defining an edge over the contact area, forming a spacer layer over the spacer, the spacer layer conforming to the shape of the first sacrificial layer such that the spacer layer comprises an edge portion over the contact area adjacent the first sacrificial layer edge, removing the sacrificial layer, while retaining the edge portion of the spacer layer over the contact area, forming a dielectric layer over the contact area, removing the edge portion, and forming a programmable material to the contact area formerly occupied by the edge portion.

Abstract: A cleaning method for semiconductor manufacturing process. A to-be-cleaned wafer having a metal layer thereon is provided. The wafer is placed into a chemical cleaning equipment unit to clean the wafer surface with a chemical cleaning solution while protecting the metal layer by a cathodic protection method. Next, the chemical cleaning solution on the wafer surface is rinsed away and the wafer is then dried to complete the cleaning method.

Abstract: An integrated circuit includes first and second diodes that are electrically connected to a conductive line in antiparallel, to dissipate both positive and negative charges on the conductive line during plasma processing. The integrated circuit also includes a fuse for disconnecting one of the first and second diodes from the conductive line after the plasma processing, to thereby allow conduction of one of positive and negative charge on the conductive line after the plasma processing. Accordingly, integrated circuits are fabricated by forming a conductive line on an integrated circuit substrate and first and second diodes in the integrated circuit substrate that are electrically connected to the conductive line in antiparallel. Then, plasma processing is performed on the integrated circuit substrate including the conductive line and the first and second diodes, such that the first and second diodes dissipate both positive and negative charges on the conductive line during the plasma processing.

Abstract: Pathways to rapid and reliable fabrication of nanocylinder arrays are provided. Simple methods are described for the production of well-ordered arrays of nanopores, nanowires, and other materials. This is accomplished by orienting copolymer films and removing a component from the film to produce nanopores, that in turn, can be filled with materials to produce the arrays. The resulting arrays can be used to produce nanoscale media, devices, and systems.

Abstract: An exemplary embodiment of the present invention includes a method for forming a programmable cell by forming an opening in a dielectric material to expose a portion of an underlying first conductive electrode, forming a recessed chalcogenide-metal ion material in the opening and forming a second conductive electrode overlying the dielectric material and the chalcogenide-metal ion material. A method for forming a recessed chalcogenide-metal ion material comprises forming a glass material to be recessed approximately 50% or less, in the opening in the dielectric material, forming a metal material on the glass material within the opening and diffusing metal ions from the metal material into the glass material by using ultraviolet light or ultraviolet light in combination with a heat treatment, to cause a resultant metal ion concentration in the glass material.

Abstract: In order to separate first and second base substrate without cracking them, and use a damaged base substrate again as a semiconductor substrate to enhance a yield, there is disclosed a preparation method of a semiconductor substrate comprising the steps of separating a composite member formed by bonding the first and second base substrates to each other via an insulating layer into a plurality of members at a separation area formed in a position different from a bonded face to transfer a part of one base substrate onto the other base. A mechanical strength of the separation area is non-uniform along the bonded face in the composite member.

Abstract: A method for electrically contacting a rear side of a semiconductor substrate when processing the semiconductor substrate includes the step of placing the semiconductor substrate with a substrate rear side on a substrate holder such that an electrically conductive contact layer formed of a semiconductor material is disposed between the semiconductor substrate and the substrate holder.

Abstract: A surface PIN (SPIN) device and a method of fabricating such a SPIN device. The SPIN device, when activated, confines carrier injection to a small volume near the surface of the device such that the device is sufficiently conductive to simulate a planar conductor. The SPIN device comprises a P+ region and an N+ region formed in an intrinsic (I) layer. The P+ and N+ regions are separated by a lateral length of intrinsic material of length L. The length L is approximately the carrier diffusion length. When DC bias is applied across the N+ and P+ regions carriers are injected into the intrinsic region at a density exceeding 1018 carriers per cubic cm. The intrinsic region is sufficiently thin to confine the carriers near the surface of the intrinsic region. As such, in the “on” state, the SPIN device simulates a conductive material. In the “off” state, the SPIN device is no longer conductive.

Abstract: This invention relates to a method of depositing dielectric on a semiconductor substrate to form part of a capacitor. The method includes reactive sputtering a metal oxide layer from a target of metal onto the substrate wherein the support is biased to induce a DC voltage across the depositing dielectric as it forms. The voltage may be in the range of 200-300V.

Abstract: A method of crystallizing an amorphous film comprises the steps of forming an amorphous film capable of being crystallized on a substrate, the amorphous film being in contact with a Co thin film, and crystallizing the amorphous film by forming and electric field in the amorphous film and the Co thin film, while simultaneously subjecting the amorphous film and the Co thin film to a thermal treatment, thereby crystallizing the amorphous film.

Abstract: The present invention discloses a method of manufacturing a thin film transistor, including: depositing an amorphous silicon layer, an insulating layer, and a gate metal layer on a substrate sequentially; patterning the insulating layer and the gate metal layer to form a gate insulating layer and a gate electrode; treating an impurity and a catalyst metal on the amorphous silicon layer using the gate electrode as a mask; and applying a DC voltage to both terminals of the amorphous silicon layer to form a polysilicon layer, the polysilicon layer having source and drain regions and an active area.

Abstract: A method of forming a high polysilicon resistor over a dielectric layer, comprising the following steps. A polysilicon resistor over a semiconductor structure is provided. The polysilicon resistor has a doped polysilicon layer having a first voltage coefficient of resistance and grain boundaries having a first trapping density. A to a first level of DC current is provided for a predetermined duration through the doped polysilicon layer to stress the doped polysilicon layer to partially melt the doped polysilicon layer without causing breakdown of the doped polysilicon layer. The to a first level of DC current is removed to allow recrystallization of the melted doped polysilicon layer, whereby the recrystallized doped polysilicon layer has a second voltage coefficient of resistance less than the first voltage coefficient of resistance and grain boundaries having a second trapping density that is less than the first trapping density. This makes the Rs of the polysilicon to be stable and saturated.

Abstract: An electrical and thermal contact for use in a semiconductor device. The electrical and thermal contact includes an intermediate conductive layer, an insulator component, and a contact layer. The intermediate conductive layer may contact a structure of the semiconductor device. The insulator component, which is fabricated from a thermally and electrically insulative material, may be sandwiched between the intermediate conductive layer and the contact layer, which may substantially envelop the insulator component.

Abstract: The invention encompasses methods of forming individual silicon-on-insulator layers having varying thicknesses within the individual layers. The invention also encompasses methods of forming transistor devices from silicon-on-insulator layers. Additionally, the invention encompasses semiconductor devices and assemblies utilizing silicon-on-insulator layers. The invention includes a method comprising: a) providing a substrate; b) providing an insulator layer over the substrate; c) providing a semiconductive layer over the insulator layer, the semiconductive layer having a first portion and a second portion; d) forming a depletion region within the semiconductive layer and proximate the insulator layer, the depletion region having a different thickness in the first portion than in the second portion; and f) etching the semiconductive layer to about the depletion region.

Abstract: A method of providing nickel barrier end terminations for a zinc oxide semiconductor device with exposed body surfaces and end terminal regions, in which the device is controllably reacted with a nickel plating solution only on an exposed end terminal region and thereafter provided with a final tin or tin-lead termination.

Abstract: A method of programming a semiconductor memory includes forming a multiplicity of fuse links in at least two mutually parallel planes in a semiconductor body, and separating the fuse links from one another with an electrical insulator. It also includes irradiating a selected fuse link with at least two laser beams and melting the selected fuse link by crossing the laser beams at the selected fuse link.

Abstract: A method for plating conductive material in through apertures and blind apertures of a substrate which has a conductive material on its upper and lower surfaces. In a typical configuration for plating a via, there is a first region of conductive material adjacent to, but outside of, the aperture which forms the via and a second region of conductive material inside of the aperture. The second conductive region is selected to be the cathode of the plating process. The structure is placed in a plating bath, a first potential is applied to the first region of conductive material, and a second potential is applied to the second region of conductive material, with the second potential being different from the first potential. Under these conditions, material will plate onto the second region of conductive material to fill the aperture.

Abstract: A method to obtain the same effect as that of burning in at an operating frequency of a high-frequency transistor by burning in at a frequency lower than the operating frequency. Burn-in is carried out using a frequency lower than the operating frequency of the transistor and higher than the response frequency of impurities included in the transistor.

Abstract: The invention encompasses methods of forming individual silicon-on-insulator layers having varying thicknesses within the individual layers. The invention also encompasses methods of forming transistor devices from silicon-on-insulator layers. Additionally, the invention encompasses semiconductor devices and assemblies utilizing silicon-on-insulator layers. The invention includes a method comprising: a) providing a substrate; b) providing an insulator layer over the substrate; c) providing a semiconductive layer over the insulator layer, the semiconductive layer having a first portion and a second portion; d) forming a depletion region within the semiconductive layer and proximate the insulator layer, the depletion region having a different thickness in the first portion than in the second portion; and f) etching the semiconductive layer to about the depletion region.