Abstract: In manufacturing an LSI, or semiconductor integrated circuit device, the step of assembling device (such as resin sealing step) is normally followed by a voltage-application test in an environment of high temperature (e.g., from 85 to 130° C.) and high humidity (e.g., about 80% RH). It has been found that separation of a titanium nitride anti-reflection film from an upper film and generation of cracks in the titanium nitride film at an upper surface edge part of the aluminum-based bonding pad applied with a positive voltage in the test is caused by an electrochemical reaction due to moisture incoming through the sealing resin and the like to generate oxidation and bulging of the titanium nitride film. These problems are addressed by removing the titanium nitride film over the pad in a ring or slit shape at peripheral area of the aluminum-based bonding pad.

Abstract: An integrated circuit containing hydrogen permeable dummy vias configured in a linear or rectangular array and symmetrically positioned over a component in the integrated circuit. An integrated circuit containing matching components with identical layouts and hydrogen permeable dummy vias in identical configurations over the matching components. A process of forming an integrated circuit containing matching components with identical layouts and hydrogen permeable dummy vias in identical configurations over the matching components.

Abstract: Conductive structures include a plurality of conductive steps and a contact extending at least partially therethrough in communication with at least one of the plurality of conductive steps and insulated from at least another one of the conductive steps. Devices may include such conductive structures. Systems may include a semiconductor device and a stair step conductive structure having a plurality of contacts extending through a step of the stair step conductive structure. Methods of forming conductive structures include forming contacts in contact holes formed through at least one conductive step of a conductive structure. Methods of forming electrical connections in stair step conductive structures include forming contacts in contact holes formed through each step of the stair step conductive structure.

Abstract: A method of forming an integrated circuit, including providing a first substrate layer having a center piece and two side pieces on opposite sides of the center piece, assembling one or more circuit elements on a top side and a bottom side of the center piece of the first substrate layer, preparing two support pieces from a substrate, matching the size of the side pieces, coupling the support pieces to the bottom of the first substrate layer under the side pieces to form a second substrate layer with a void in the center under the center piece of the first substrate layer; and wherein the side pieces and support pieces include via connectors electrically connecting between a bottom side of the second substrate layer and the circuit elements.

Abstract: A semiconductor device and a method of fabricating the same are provided. The semiconductor device includes a substrate including a first region and a second region, a first transistor and a second transistor formed on the first region and the second region, respectively, a first contact formed on the first transistor, and a second contact formed on the second transistor. The first contact includes a first work function control layer having a first thickness and a first conductive layer formed on the first work function control layer, the second contact includes a second work function control layer having a second thickness different from the first thickness and a second conductive layer formed on the second work function control layer, and the first contact and the second contact have different work functions.

Abstract: A semiconductor device structure is provided. The semiconductor device structure includes a first metal layer formed over a substrate and an interconnect structure formed over the first metal layer. The interconnect structure includes an upper portion, a middle portion and a lower portion, the middle portion is connected between the upper portion and the lower portion. The upper portion and the lower portion each have a constant width, and the middle portion has a tapered width which is gradually tapered from the upper portion to the lower portion.

Abstract: The present disclosure relates to a semiconductor structure which includes a first row of diffusion strap having two sections separated by a first distance, a second row of diffusion strap having two sections separated by the first distance, a third row of diffusion strap having two sections separated by the first distance, a fourth row of diffusion strap having two sections separated by the first distance, a first row of conductive strap over the first row of diffusion strap and the second row of diffusion strap, and a second row of conductive strap over the third row of diffusion strap and the fourth row of diffusion strap. The first row of conductive strap has two sections separated by a second distance. The second row of conductive strap has having two sections separated by the second distance, wherein the second distance is greater than the first distance.

Abstract: On a semiconductor substrate, coils CL5 and CL6 and pads PD5, PD6, and PD7 are formed. The coil CL5 and the coil CL6 are electrically connected in series between the pad PD5 and the pad PD6, and the pad PD7 is electrically connected between the coil CL5 and the coil CL6. The coil magnetically coupled to the coil CL5 is formed just below the coil CL5, the coil magnetically coupled to the coil CL6 is formed just below the coil CL6, and they are connected in series. When a current is flowed in the coils connected in series formed just below the coils CL5 and CL6, directions of induction current flowing in the coils CL5 and CL6 are opposed to each other in the coils CL5 and CL6.

Abstract: An method including forming a back end of the line (BEOL) wiring portion directly on top of a semiconductor base portion, the BEOL wiring portion including a plurality of layers of a metallic material and a dielectric material and excluding a semiconductor material, forming a through-substrate via through the BEOL wiring portion and the semiconductor base portion, forming an electronic fuse in the BEOL wiring portion adjacent to the through-substrate via, and forming a guard ring in the BEOL wiring portion surrounding the through-substrate via and the electronic fuse in the BEOL wiring portion, the through-substrate via in the semiconductor base portion being free from the guard ring.

Abstract: An interconnect structure and method of making the same. A preferred interconnect structure has a first interconnect including a first dual damascene via and narrow line and a second interconnect at the same level as the first including a second dual damascene via and wider line. The first and second interconnects may have different aspect ratio and may have different line heights while being co-planar with each other. The second line of the second interconnect may abut or partially surround the first line of the first interconnect. The first interconnect includes a refractory metal material as the main conductor, whereas the second interconnect includes a lower resistivity material as its main conductor.

Abstract: A semiconductor device is disclosed. The semiconductor device includes: a substrate having a die region and a scribe line region defined thereon; and a bonding pad on the die region of the substrate and overlapping the scribe line region.

Abstract: A method of forming an interconnect structure includes providing a first dielectric layer, patterning a wire opening in a first dielectric layer, lining the wire opening with a metal liner and includes filling the wire opening with a first conductive material. The method also includes depositing a first cap on the first dielectric layer, depositing a second dielectric layer, and patterning a via trench in the second dielectric layer. The method also includes depositing a metal liner, removing the metal liner from a via junction, and enlarging the contact area. The method also includes filling the via trench with a second conductive material to form a via.

Abstract: A semiconductor device may include a metal pad and a first specific metal layer routing. The metal pad is positioned on a first metal layer of the semiconductor device and is directly contacting the first metal layer. The first specific metal layer routing is formed on a second metal layer of the semiconductor device and under the metal pad. In addition, the semiconductor device may include at least one via plug for connecting the first specific metal layer routing to at least one metal region in the first metal layer, where the aforementioned at least one via plug is formed directly under the metal pad.

Abstract: The present disclosure relates to a method of forming a back-end-of-the-line metallization layer. The method is performed by forming a plurality of freestanding metal layer structures (i.e., metal layer structures not surrounded by a dielectric material) on a semiconductor substrate within an area defined by a patterned photoresist layer. A diffusion barrier layer is deposited onto the metal layer structure in a manner such that the diffusion barrier layer conforms to the top and sides of the metal layer structure. A dielectric material is formed on the surface of the substrate to fill areas between metal layer structures. The substrate is planarized to remove excess metal and dielectric material and to expose the top of the metal layer structure.

Abstract: A semiconductor device includes a first gate electrode provided in a jumper region of a substrate and extending in a first direction, first source/drain regions provided at both sides of the first gate electrode, and a connecting contact electrically connecting the first gate electrode and the first source/drain regions to each other. The connecting contact includes first sub-contacts disposed at both sides of the first gate electrode and connected to the first source/drain regions, and a second sub-contact extending in a second direction intersecting the first direction. The second sub-contact is connected to the first sub-contacts and is in contact with a top surface of the first gate electrode. In the first direction, each of the first sub-contacts has a first width and the second sub-contact has a second width smaller than the first width.

Abstract: An MIS contact structure comprises a layer of semiconductor material, a layer of insulating material having a contact opening formed therein, a layer of contact insulating material having substantially vertically oriented portions and a substantially horizontally oriented portion, the vertically oriented portions of the layer of contact insulating material contacting a portion, but not all, of the sidewalls of the contact opening and the horizontally oriented portion of the layer of contact insulating material contacting the semiconductor layer. A conductive material is positioned on the layer of contact insulating material within the contact opening, the conductive material layer having vertically oriented portions and a horizontally oriented portion and a conductive contact positioned in the contact opening that contacts the uppermost surfaces of the conductive material layer and the layer of contact insulating material.

Abstract: A TSV via structure comprising an upper part made on the side of the front face of a substrate in which electronic components are located and a lower part with height and cross-section smaller than the height and cross-section the upper part, the arrangement of the connection element in the substrate being such that it releases stresses generated by the different materials of said structure.

Abstract: An embodiment of a method of manufacturing semiconductor wafers comprises forming a notch or a flat in a semiconductor ingot extending along an axial direction. A plurality of markings are formed in the semiconductor ingot. At least some of the plurality of markings at different positions along the axial direction are distinguishable from each other by a characteristic feature. The semiconductor ingot is then sliced into semiconductor wafers.

Abstract: To provide a technique capable of positioning of a semiconductor chip and a mounting substrate with high precision by improving visibility of an alignment mark. In a semiconductor chip constituting an LCD driver, a mark is formed in an alignment mark formation region over a semiconductor substrate. The mark is formed in the same layer as that of an uppermost layer wiring (third layer wiring) in an integrated circuit formation region. Then, in the lower layer of the mark and a background region surrounding the mark, patterns are formed. At this time, the pattern P1a is formed in the same layer as that of a second layer wiring and the pattern P1b is formed in the same layer as that of a first layer wiring. Further, the pattern P2 is formed in the same layer as that of a gate electrode, and the pattern P3 is formed in the same layer as that of an element isolation region.

Abstract: A three-dimensional (3-D) integrated circuit (3DIC) with a graphene shield is disclosed. In certain embodiments, at least a graphene layer is positioned between two adjacent tiers of the 3DIC. A graphene layer is a sheet like layer made of pure carbon, at least one atom thick with atoms arranged in a regular hexagonal pattern. A graphene layer may be disposed between any number of adjacent tiers in the 3DIC. In exemplary embodiments, the graphene layer provides an electromagnetic interference shield between adjacent tiers or layers in the 3DIC to reduce crosstalk between the tiers. In other exemplary embodiments, the graphene layer(s) can be disposed in the 3DIC to provide a heat sink that directs and dissipates heat to peripheral areas of the 3DIC. In some embodiments, the graphene layer(s) are configured to provide both EMI shielding and heat shielding.

Abstract: A semiconductor package includes a substrate having a front side, a bottom side, and a sidewall along a perimeter of the substrate, a plurality of solder pads on the bottom side, at least one EM shielding contact structure on the bottom side and partially exposed on the sidewall, a semiconductor device mounted on the front side, a mold compound on the front side and covering the semiconductor device, and an EM shielding layer conformally covering the mold compound and the sidewall. The EM shielding layer is in direct contact with the exposed portion of the EM shielding contact structure on the sidewall.

Abstract: An method including forming multiple interconnect levels on top of one another, each level comprising a metal interconnect and a crack stop both embedded in a dielectric layer, and a dielectric capping layer directly on top of the dielectric layer and directly on top of the metal interconnect, the crack stop is an air gap which intersects an interface between the dielectric layer and the dielectric capping layer of each interconnect level, and forming a through substrate via through the multiple interconnect levels adjacent to, but not in direct contact with, the crack stop, the crack stop of each interconnect level is directly between the metal interconnect of each interconnect level and the through substrate via to prevent cracks caused during fabrication from propagating away from the through substrate via and damaging the metal interconnect.

Abstract: According to one embodiment, a semiconductor package includes: a first metal body on which a part of a waveguide structure is formed; a second metal body including a mounting area for a semiconductor device and disposed on the first metal body; a line substrate on which a signal transmission line configured to communicate a waveguide with the semiconductor device mounted on the mounting area is formed; and a lid body disposed at a position facing the first metal body, interposing the second metal body and the line substrate. The lid body is made of resin, on which a structure corresponding to another waveguide structure on an extension of the waveguide structure in the first metal body is formed. The structure includes a metal-coated inner wall surface.

Abstract: The disclosed antenna structures and electronic microsystems are capable of physically disappearing in a controlled, triggerable manner. Some variations provide an on-chip transient antenna comprising a semiconductor substrate containing ion-implanted hydrogen atoms and a conductor network comprising metals bridged by low-melting-temperature metals. Some variations provide an off-chip transient antenna comprising a flexible substrate containing a polymer, nanoporous silicon particles, and an oxidant for silicon, and a conductor network comprising metals bridged by low-melting-temperature metals. Other variations provide a method of introducing physical transience to a semiconductor integrated circuit, comprising thinning a substrate from the back side, implanting hydrogen ions into the thinned substrate to introduce latent structural flaws, depositing a semiconductor integrated circuit or sensor chip, and providing a controllable heating source capable of activating the latent structural flaws.

Abstract: RF transmission device including at least: a substrate comprising first and second faces opposite to each other; a first RF transmission electronic circuit arranged on and/or in the substrate; a first antenna arranged on the side of the first face of the substrate, spaced apart from the first face of the substrate and electrically connected to the first RF transmission electronic circuit; a first electromagnetic wave reflector coupled to the first antenna and including: a first high impedance surface comprising at least several first electrically conducting elements forming a first periodic structure and arranged on the first face of the substrate opposite the first antenna; a first electrically conducting ground plane arranged at least partially opposite the first antenna.

Abstract: A semiconductor device includes a chip body having an uneven surface including at least two regions at different levels from one another, a through electrode penetrating the chip body and having an end which is exposed by the uneven surface of the chip body, a passivation layer disposed on the uneven surface of the chip body, and a bump disposed on the passivation layer and the exposed end of the through electrode and overlapping with the uneven surface of the chip body.

Abstract: An embodiment is a bump bond pad structure that comprises a substrate comprising a top layer, a reinforcement pad disposed on the top layer, an intermediate layer above the top layer, an intermediate connection pad disposed on the intermediate layer, an outer layer above the intermediate layer, and an under bump metal (UBM) connected to the intermediate connection pad through an opening in the outer layer. Further embodiments may comprise a via mechanically coupling the intermediate connection pad to the reinforcement pad. The via may comprise a feature selected from the group consisting of a solid via, a substantially ring-shaped via, or a five by five array of vias. Yet, a further embodiment may comprise a secondary reinforcement pad, and a second via mechanically coupling the reinforcement pad to the secondary reinforcement pad.

Abstract: Methods for preparing 3D integrated semiconductor devices and the resulting devices are disclosed. Embodiments include forming a first and a second bond pad on a first and a second semiconductor device, respectively, the first and the second bond pads each having plural metal segments, the metal segments of the first bond pad having a configuration different from a configuration of the metal segments of the second bond pad or having the same configuration as a configuration of the metal segments of the second bond pad but rotated with respect to the second bond pad; and bonding the first and second semiconductor devices together through the first and second bond pads.

Abstract: A semiconductor device includes a semiconductor substrate, a pad electrode formed on the semiconductor substrate, a post electrode formed on the pad electrode and made of a copper film, a solder ball electrode formed on the post electrode and made of ternary alloy containing tin, a terminal connected to the solder ball electrode and formed on a front surface of a wiring board, and a sealing material filling a gap between the semiconductor substrate and the wiring board. The post electrode includes a cylindrical stem portion and an overhanging portion positioned in an upper part of the stem portion and protruding to an outer side of the stem portion, the solder ball electrode is connected to an upper surface of the post electrode over the stem portion and the overhanging portion, and a sidewall of the stem portion contacts with the sealing material over the entire circumference thereof.

Abstract: A package and method of making the package are provided. An embodiment package includes an integrated circuit supporting a conductive pillar, a substrate having a landing pad on each embedded metal trace, a landing pad width greater than a corresponding embedded metal trace width, and a conductive material electrically coupling the conductive pillar to the landing pad. In an embodiment, the landing pad overlaps the metal trace in one direction.

Abstract: A preform structure for soldering a semiconductor chip arrangement includes a carbon fiber composite sheet and a solder layer formed over the carbon fiber composite sheet.

Abstract: Embodiments described herein relate to a packaged circuit including a lead frame having at least one recess pattern on an internal surface thereof. The at least one recess pattern includes a perimeter recess that defines a perimeter around one or more raised surfaces. The packaged circuit also includes a component having one or more terminals. One of the terminals is mounted to the one or more raised surfaces such that the terminal covers the perimeter recess, wherein the perimeter recess has a size and shape such that the recess is proximate a perimeter of the terminal. The packaged circuit also includes component attach adhesive between the single terminal of the component and the one or more raised surfaces of the lead frame.

Abstract: According to at least one embodiment of the present invention, a wafer-to-wafer semiconductor device includes a first wafer substrate having a first bonding layer formed on a first bulk substrate layer. A second wafer substrate includes a second bonding layer formed on a second bulk substrate layer. The second bonding layer is bonded to the first bonding layer to define a bonding interface. At least one of the first wafer substrate and the second wafer substrate includes a crack-arresting film layer configured to increase a bonding energy of the bonding interface.

Abstract: Bonding wire for semiconductor device use where both leaning failures and spring failures are suppressed by (1) in a cross-section containing the wire center and parallel to the wire longitudinal direction (wire center cross-section), there are no crystal grains with a ratio a/b of a long axis “a” and a short axis “b” of 10 or more and with an area of 15 ?m2 or more (“fiber texture”), (2) when measuring a crystal direction in the wire longitudinal direction in the wire center cross-section, the ratio of crystal direction <100> with an angle difference with respect to the wire longitudinal direction of 15° or less is, by area ratio, 50% to 90%, and (3) when measuring a crystal direction in the wire longitudinal direction at the wire surface, the ratio of crystal direction <100> with an angle difference with respect to the wire longitudinal direction of 15° or less is, by area ratio, 50% to 90%. During the drawing step, a drawing operation with a rate of reduction of area of 15.

Abstract: A semiconductor device includes, an alloy layer sandwiched between a first Ag layer formed on a mounting board or circuit board and a second Ag layer formed on a semiconductor element, wherein the alloy layer contains an intermetallic compound of Ag3Sn formed by Ag components of the first Ag layer and the second Ag layer and Sn, and wherein a plurality of wires containing Ag are arranged extended from an outside-facing periphery of the alloy layer.

Abstract: Provided is a flip chip bonder including: a pickup flipping collet configured to flip a chip; and a bonding tool configured to receive the chip flipped with the pickup flipping collet from the pickup flipping collet and to bond the received chip to a circuit board. The pickup flipping collet includes a cooling channel through which cooling air flows to cool the pickup flipping collet. Thus, bonding time can be reduced without lowering bonding quality.

Abstract: A heating header of a semiconductor mounting apparatus includes: a first material; and a second material, the second material being bonded to the first material and coming into contact with a first semiconductor chip when the first semiconductor chip is compressed, wherein a contact surface of the second material with the first semiconductor chip is a curved surface that is convex toward the first semiconductor chip side, and the contact surface of the second material with the first semiconductor chip becomes a planar surface when each temperature of the first material and the second material reaches a melting temperature of a solder that is formed between a first terminal of the first semiconductor chip and a second terminal of a second semiconductor chip.

Abstract: Provided are a semiconductor device including an interposer having a relatively thin thickness without a through silicon via and a method of manufacturing the same. The method of manufacturing a semiconductor device includes forming an interposer including a redistribution layer and a dielectric layer on a dummy substrate, connecting a semiconductor die to the redistribution layer facing an upper portion of the interposer, encapsulating the semiconductor die by using an encapsulation, removing the dummy substrate from the interposer, and connecting a bump to the redistribution layer facing a lower portion of the interposer.

Abstract: A semiconductor device includes a semiconductor element, a lead, and a wire including a first bonding portion bonded to the semiconductor element and a second bonding portion bonded to the lead. The semiconductor element includes a first bonding surface which faces to a first side in a first direction and to which the first bonding portion is bonded. The lead includes a second bonding surface and a third bonding surface both facing to the first side in the first direction and forming an angle larger than 180° on the first side in the first direction. The semiconductor device further includes a ball bump extending onto both the second bonding surface and the third bonding surface. The second bonding portion is bonded to the lead via the ball bump.

Abstract: A stretchable display is disclosed. In one aspect, the stretchable display includes a plurality of pixel substrates arranged in a matrix having row and column directions. Each of the pixel substrates includes an island and a flexible hinge connecting the island to at least one of the adjacent pixel substrates. The island of each of the pixel substrates includes a plurality of first sides and a plurality of second sides. The flexible hinge of each of the pixel substrates includes a plurality of first flexible sub-hinges respectively extending from the first sides in the row direction and a plurality of second flexible sub-hinges respectively extending from the second sides in the column direction.

Abstract: A semiconductor package may include a substrate having a first surface and a second surface facing away from the first surface, a window defined through a center portion of the substrate, and a plurality of first bond fingers, a plurality of second bond fingers, and a plurality of external electrodes arranged on the second surface; two or more first semiconductor chips each having a plurality of first bonding pads arranged adjacent to edges of the first semiconductor chips, and each of the first semiconductor chips separately attached to the first surface of the substrate in a face-down type position exposing the first bonding pads; and a second semiconductor chip having a plurality of second bonding pads arranged at a center portion of the second semiconductor chip, and attached to each of the first semiconductor chips in a face-down type position exposing the second bonding pads through the window.

Abstract: Semiconductor integrated circuits (110) or assemblies are disposed at least partially in cavities between two interposers (120). Conductive vias (204M) pass through at least one of the interposers or at least through the interposer's substrate, and reach a semiconductor integrated circuit or an assembly. Other conductive vias (204M.1) pass at least partially through multiple interposers and are connected to conductive vias that reach, or are capacitively coupled to, a semiconductor IC or an assembly. Other features are also provided.

Abstract: Apparatuses for interconnecting integrated circuit dies. A first set of single-ended transmitter circuits are included on a first die. The transmitter circuits are impedance matched and have no equalization. A first set of single-ended receiver circuits are included on a second die. The receiver circuits have no termination and no equalization. Conductive lines are coupled between the first set of transmitter circuits and the first set of receiver circuits. The lengths of the conductive lines are matched. The first die, the first set of single-ended transmitter circuits, the second die, the first set of single ended receiver circuits and the conductive lines are disposed within a first package. A second set of single-ended transmitter circuits are included on the first die. The transmitter circuits are impedance matched and have no equalization. Data transmitted from the second set of transmitter circuits is transmitted according to a data bus inversion (DBI) scheme.

Abstract: This disclosure provides a package structure and its fabrication method. The package structure includes: a protective insulation layer; a wiring layer including at least one metal wire and disposed on the protective insulation layer; and a first package unit disposed on the wiring layer and including a plurality of metal pillars, a first integrated-circuit chip and a first molding compound layer; wherein the plural metal pillars are located in a pillar region and electrically connected to the at least one metal wire, the first integrated-circuit chip is located in a device region and electrically connected to the at least one metal wire, and the first molding compound layer filling up the remaining part of the first package unit.

Abstract: An embodiment method includes analyzing warpage characteristics of a first package component and a second package component and forming a plurality of solder paste elements on the first package component. A volume of each of the plurality of solder paste elements is based on the warpage characteristics of the first package component and the second package component. The method further includes aligning a plurality of connectors disposed on the second package component to the plurality of solder paste elements on the first package component and bonding the second package component to the first package component by reflowing the plurality of connectors and the plurality of solder paste elements.

Abstract: The present disclosure provides a semiconductor device. A first active region is formed in a substrate. The first active region is elongated in a first direction in a top view. A first gate is formed over the substrate. The first gate is elongated in a second direction in the top view. A portion of the first gate is located over the first active region. A second gate is formed over the substrate. The second gate is elongated in the second direction in the top view. A portion of the second gate is located over the first active region. The second gate is shorter than the first gate in the second direction.

Abstract: A semiconductor device includes a plurality of bit lines that intersect an active region on a substrate and extend in a first direction, a contact pad formed on the active region between adjacent bit lines, and a plurality of spacers disposed on sidewalls of the plurality of bit lines. An upper portion of the contact pad is interposed between adjacent spacers, and a lower portion of the contact pad has a width greater than a distance between adjacent spacers.

Abstract: An electrostatic discharge protection apparatus comprises a stack arrangement having a first electrostatic discharge protection element and a second electrostatic discharge protection element. The stack arrangement is arranged to provide a bias potential between the first and second electrostatic discharge protection elements. In one embodiment, the bias potential can be achieved by a clamp arrangement coupled across the stack arrangement.

Abstract: An electrostatic discharge protection circuit is disclosed. A method of manufacturing a semiconductor structure includes forming a semiconductor controlled rectifier including a first plurality of fingers between an n-well body contact and an anode in an n-well, and a second plurality of fingers between a p-well body contact and a cathode in a p-well.

Abstract: Various aspects of the technology include an integrated circuit device comprising a compound semiconductor layer and a plurality of input, switch, and ground ohmic metal fingers fabricated on the compound semiconductor layer in a repeating sequence. A control gate may be disposed between each input finger and adjacent switch finger, and a sync gate may be disposed between each ground finger and adjacent switch finger. A sync gate and a control gate may be disposed adjacent each switch finger. The device further includes a plurality of control gate pads, each control gate pad at an end of two control gates, and a control gate pad at opposite ends of each control gate, and a plurality of sync gate pads, each sync gate pad at an end of two sync gates, and a sync gate pad at opposite ends of each sync gate.