Components having voltage switchable dielectric materials

Abstract

Various aspects provide for structures and devices to protect against spurious electrical events (e.g., electrostatic discharge). Some embodiments incorporate a voltage switchable dielectric material (VSDM) bridging a gap between two conductive pads. Normally insulating, the VSDM may conduct current from one pad to the other during a spurious electrical event (e.g., shunting current to ground). Some aspects include gaps having a gap width that is greater than 50% of a spacing between electrical leads connected to the pads. Some devices include single layers of VSDM. Some devices include multiple layers of VSDM. Various devices may be designed to increase a ratio of active volume (of VSDM) to inactive volume.

Description

BACKGROUND

1. Technical Field

The present invention relates to designing and fabricating devices that incorporate voltage switchable dielectric materials.

2. Description of Related Art

A printed circuit board, printed wiring board, integrated circuit (IC) package, or similar substrate (hereinafter, PCB) may be used to assemble and connect electronic components. A PCB typically includes a dielectric material and one or more conductive leads to provide electrical conductivity among various attached components, chips, and the like. Leads may be metallic, and are often formed using lithographic techniques (e.g., as a layer of Cu which is subsequently etched)

Various components may be attached to a PCB. Attachment may include soldering (e.g., reflowing), wire bonding, ultrasonic bonding, and the like. For applications requiring the attachment of several components to a PCB, the available “attachment area” on a surface of the PCB may limit the size and/or number of components that may be attached. Reducing the size of (and thus the surface area occupied by) an attached component may yield increased remaining area on the PCB surface, which may be used for attaching further components or larger components.

Various electrical and electronic components may benefit from surge protection, protection against electrostatic discharge (ESD) and protection against other spurious electrical events. ESD protection may include incorporating a voltage switchable dielectric material (VSDM). A VSDM may behave as an insulator at a low voltage, and a conductor at a higher voltage. A VSDM may be characterized by a so-called “switching voltage” between these states of low and high conductivity. A VSDM may shunt (e.g., to a ground) current that would otherwise damage a component by becoming conductive at voltages above the switching voltage and allowing currents at these voltages to pass to ground through the VSDM, rather than through the device being protected.

Some PCB components may be protected against electrical surges by attaching a surge protection device (e.g., a device incorporating a VSDM). In such cases, an attached surge-protection device may take up “attachable” regions (e.g., surface area) of the assembly. In such cases, minimizing the area of the device (while meeting requisite properties) may increase the available area for attachment of other components and/or minimize the overall size of the PCB assembly.

SUMMARY OF THE INVENTION

Various aspects provide for a device incorporating a voltage switchable dielectric material (VSDM). A VSDM may include a substantially insulating phase (e.g., one or more polymers) and a substantially conductive phase (e.g., one or more metals). A VSDM may include a semiconducting phase. In some implementations, an insulating phase may be substantially continuous, with discrete conductive and/or semiconducting phases (e.g., metallic and semiconducting particles dispersed in a polymer matrix at a concentration near a percolation threshold associated with the particles).

The device may include first and second conductive leads, which may be separated by a distance described as a “package spacing.” The first lead may be connected to or otherwise in electrical communication with a first conductive pad, and the second lead may be connected or otherwise in electrical communication with a second conductive pad. The first and second pads may be separated by a first gap. The first gap may have a gap width greater than 50% 70%, or even 90% of the package spacing. The first gap may be larger than (e.g., 2 times, 3 times, 5 times, 10 times, 50 times, or even 100 times larger than) the package spacing. The first and second pads may be attached to the VSDM, and the first gap may be bridged by the VSDM, such that at voltages above the switching voltage, current may pass from one pad to the other via the VSDM, substantially “across” the first gap.

Certain embodiments include multilayer stacks of single layer devices (e.g., pairs of complementary pads on different layers). In some cases, a third conductive pad may be electrically connected to the first lead with a via (e.g., through a multilayer stack), and a fourth conductive pad may be electrically connected to the second lead with a via. A second VSDM (which may be different or the same as the first VSDM) may contact both the third and fourth pads, and may bridge a second gap separating the third and fourth pads. The first and second gaps may be the same or different. Some gaps may be fabricated using lithographic methods, which may provide for tightly controlled dimensional tolerance on the gap as compared to other fabrication methods.

Various embodiments include surface mount devices, which may be compatible with standard surface mount technology (SMT) specifications. In some cases, a package spacing may correspond to a standardized specification for an assembly to which the device may be attached (e.g., a bond pad spacing on a PCB). Typical package spacings may be between hundreds of microns and tens of millimeters. Some devices include dielectric substrates (e.g., printed circuit board substrates).

Some embodiments provide for a plurality of gaps between two pads. Some embodiments provide for a plurality of gaps between more than two pads. Pads connected by a VSDM may be disposed single layer. Pads connected by a VSDM may be disposed on different layers of a multilayer stack. In some cases, several pads are electrically connected to a single lead (e.g., a lead configured to be attached to ground). In some cases, a device may protect several different components, each of which may be attached to a separate lead in electrical communication with a pad. The pad may be separated from another pad (e.g., a ground pad) by a gap, and the gap may be bridged by VSDM, such that during an ESD event, current flows from one pad to the other via the VSDM, substantially across the gap.

BRIEF DESCRIPTION OF THE DRAWINGS

FIGS. 1A and 1B illustrate an exemplary device incorporating a voltage switchable dielectric material (VSDM).

FIG. 2 is a schematic illustration of an active volume, according to some embodiments.

FIG. 3 illustrates a multilayer stack, according to some embodiments.

FIG. 4 illustrates a multilayer stack, according to some embodiments.

FIG. 5 illustrates an exemplary embodiment.

FIG. 6 illustrates an exemplary embodiment.

FIG. 7 illustrates an exemplary embodiment.

FIG. 8 illustrates an exemplary embodiment.

DETAILED DESCRIPTION OF THE INVENTION

Methods and apparatus may be directed toward protecting against spurious electrical events (e.g., ESD). Some devices may be designed to attach to an assembly (e.g., a PCB), protecting electronic components of the assembly that are in electrical communication with the device. For example, a component may be connected to ground via the ESD protection device, which may shunt current to ground during an ESD event but otherwise insulate the component from ground. Devices may be designed according to one or more specifications (e.g., a distance between electrical leads, solder points, wire bond points, and the like), which may be defined by or associated with an assembly to which the device may be attached.

Various embodiments provide for devices having a wide range of sizes (e.g., from below 0.5 mm^2 area to several cm^2 area). For convenience, a size of certain features (e.g., a gap width) may be described in the context of a spacing that characterizes the approximate size of a device. For the purposes of this specification, a package spacing may describe such a size of a device. A package spacing may be a generic description of a spacing between electrical leads, which may be chosen to match a corresponding spacing on another object (e.g., a package to which the device may be attached, such as a distance between bond pads on a PCB). This description is not intended to limit package spacings to packaging per se, but to provide a size scale associated with a device. A package spacing may describe a specified distance. A package spacing may qualitatively describe an approximate size of a device. Some embodiments may be directed toward small devices (e.g., having a package spacing below 1 mm). Some embodiments may be directed toward larger devices (e.g., having a package spacing above 1 cm, or even above 10 cm).

Two conductive pads may be separated by a gap and connected by voltage switchable dielectric material (VSDM), through which current passes during an electrical event. The gap may include a gap width, and the VSDM may include an active volume. Various embodiments provide for optimizing the gap width and/or active volume according to various design specifications (e.g., according to a package to which the device may be attached). For example, an embodiment may maximize gap width subject to a leakage current limitation, a maximum desired clamp voltage, and a maximum volume of the device. Certain embodiments minimize clamp voltage and size of the device by maximizing a ratio of active volume to inactive volume of VSDM.

FIGS. 1A and 1B illustrate an exemplary device incorporating a voltage switchable dielectric material. Device 100 includes at least two conductive pads (or electrodes) 110 and 112, connected by VSDM 120. Typically, one pad (e.g., pad 110) is configured to be connected to ground, and another pad (e.g., pad 112) is configured to be connected to a component being protected (e.g., a circuit, chip, resistor, capacitor, inductor, diode, and the like). Device 100 may be characterized by a package spacing 170.

Under normal operating conditions VSDM 120 behaves as an insulator, and so current at normal voltages may not pass from pad 112 to pad 110. When the device being protected is exposed to a damaging electrical event (e.g., at a voltage above the switching voltage), VSDM 120 may be conductive, and current may be shunted through VSDM 120 and pad 110 to ground.

The electrical, thermal, and physical characteristics of VSDM 120 may be a function of the chemical composition of VSDM 120. The response (e.g., shunting behavior) of device 100 may also be a function of certain geometrical factors, including gap 130, gap height 140, and gap width 150. These dimensions may generally characterize a volume of VSDM through which current passes between pads. In the example shown in FIGS. 1A and 1B, a contact area 160 may describe an area of the conductive pad that contacts the VSDM 120, and through which current passes during a shunting event. Opposing pad 112 may include another contact area to VSDM 120. Current may pass substantially uniformly through the volume of VSDM 120 (essentially defined by gap 130, height 140, and gap width 150 in FIG. 1B). In some embodiments, current may pass nonuniformly through a volume of VSDM.

FIG. 2 is a schematic illustration of an active volume, according to some embodiments. Device 200 includes pads 110 and 112 separated by gap 230. In this example, pads 110 and 112 are disposed on and connected by VSDM 120, and VSDM 120 is disposed as a layer having a thickness 240, on a dielectric substrate 202. Device 200 may be characterized by a package spacing 272, and include a gap width normal to the page of FIG. 2. Some dielectric substrates may include a layer of fiber reinforcement pre-impregnated with resin (or “prepreg”) as used in PCB fabrication. Some VSDM may be deposited on a substrate (e.g., spin coated, doctor bladed, sprayed, and the like).

Various devices (e.g., device 200) may be fabricated using lithography. For example, a printed circuit board substrate may include a VSDM layer beneath a copper layer, and conductive pads may be etched in the copper layer using lithographic techniques. In some embodiments, a mask may be applied to a VSDM layer and pads may be deposited (e.g., sputtered) through holes in the mask onto the VSDM layer. Lithographic fabrication may provide for geometries (e.g., gap, gap width, and the like) having improved tolerances as compared to devices fabricated using non-lithographic methods. In some embodiments, conductive pads, lines, vias, and the like may be fabricated using physical vapor deposition (PVD), chemical vapor deposition (CVD), electrochemical deposition (e.g., plating), electroless chemical deposition, and the like.

For some configurations, pads may be connected to VSDM in a manner that results in a variation of current density in different portions of the VSDM during shunting. For example, pads that are encapsulated in VSDM may be separated by a small gap. During shunting, a majority of current may directly traverse the gap, following the shortest route from one pad to the other pad. A smaller amount of current may follow a longer route (e.g., between portions of the pads that are separated by larger distances).

In device 200, current density through VSDM 120 during a shunting event may not be uniform with position. Certain portions of VSDM 120 (e.g., situated most closely “between” the pads and/or near the closest “corners” of pads 110 and 112) may carry more current than other portions situated farther away from the most direct connection between the pads.

Current density as a function of location in VSDM 120 may be calculated (e.g., using finite element modeling (FEM) methods), according to various parameters of the device (geometry of the pads, volume and shape of the VSDM, interfaces between the pads and the VSDM, and the like), and materials properties (e.g., composition of the VSDM such as polymer properties, fill particle properties, particle loading, thermal, electrical, mechanical properties of the phases, and the like) at a voltage and/or voltage profile associated with a given ESD event. An active volume may be defined as a volume of VSDM that carries at least a certain portion of current during a shunting event. An active volume may be chosen arbitrarily (e.g., according to an application), and may describe that volume of VSDM that carries a substantial portion (e.g., 30%, 50%, 70%, 90%, or more) of current. An active volume may be described empirically or qualitatively. In FIG. 2, active volume 270 may be generally associated with a region of VSDM 120 that carries a relatively larger amount of current between pads 110 and 112. Inactive volumes 280 may describe those regions of VSDM 120 that carry relatively little (or even none) of the current between pads 110 and 112.

Certain embodiments provide for increasing the ratio of active to inactive volume. In some applications, increasing the ratio of active volume to inactive volume may increase the proportion of VSDM that is actually shunting current during a shunting event. Increasing the ratio of active to inactive volume may provide for reducing an overall size of a device incorporating the VSDM.

For thin layers of VSDM, active volume may be increased by increasing thickness 240. Active volume may be increased by increasing gap 230, although some applications require tightly controlled electrical properties that may be substantially defined by gap 230 (i.e., gap 230 may be a “fixed parameter” according to a certain application). Certain applications provide for increasing active volume by increasing the gap width (i.e., in a direction normal to the plane of the page in FIG. 2, or alternately, gap width 150 in FIG. 1).

FIG. 3 illustrates a multilayer stack, according to some embodiments. In some implementations, gap width (normal to the page) may be increased by creating a plurality of gaps, with their respective pads connected in parallel as shown. In some cases, members of the plurality are disposed on different layers of a device. Device 300 may include VSDM layers 120, 122, 124, and 126. In some implementations, the same VSDM is used for each layer. In some implementations, different VSDMs are used in different layers. VSDM layers may be disposed on dielectric substrates. In the example shown in FIG. 3, device 300 may include a plurality of dielectric substrates 202, 204, 206, 208, which may be different or the same type of substrate.

VSDM 120 may connect pads 310 and 312 across gap 330. VSDM 122 may connect pads 320 and 322 across gap 333. VSDM 124 may connect pads 330 and 332 across gap 334. VSDM 126 may connect pads 340 and 342 across gap 336. Gaps in a device (e.g., gaps 330, 333, 334, 336) may have the same or different lengths.

A gap between pads may be between 1 and 1000 microns, including between 10 and 200 microns. Certain gaps between pads may be between 20 and 80 microns, including between 45 and 70 microns. Gaps may be fabricated (or defined between pads) using lithography. For some gaps, a tolerance on the distance between conductive pads may be within 20% of the distance. Some fabrication methods (e.g., glass mask lithography) may yield tolerances within 10% (e.g., +/−5 μm on a 50 μm gap). Some methods may yield tolerances within 5%, 1%, or even within 0.1%.

Conductive pads 310, 320, 330, and 340 may be electrically connected. In this example, these pads are connected by a conductive via 350 through the multilayer stack. Via 350 may connect to a conductive lead 360. Similarly, conductive pads 312, 322, 332, and 342 may be connected by via 352 to conductive lead 362.

A distance (e.g., a center-to-center distance) between leads 360 and 362 may be described as a package spacing, and may be defined by (or designed to fit with) a matching spacing to which device 300 may be attached. Device 300 may be characterized by a package spacing 370 between leads 360 and 362. In some embodiments, a package spacing may be between 50 microns and 1 cm, including between 250 microns and a 5 mm. Certain package spacings are in the range of 500 microns to 10 cm. A package spacing may be associated with a standard spacing (e.g., an Electronic Industries Alliance/EIA 481 standard, or an International Electrotechnical Commission/IEC standard). For example, an EIA standard surface mount device (SMD) type 0402 (1005 metric) device may be described by a package spacing of approximately 1 mm, and an 0603 device may be described by a package spacing of approximately 1.66 mm. A package spacing may be associated with a standardized surface mount technology (SMT) specification. A package spacing may characterize a dimension associated with any type of device, including but not limited to a two-terminal package (e.g., a 101005 device/400 microns; an 0201 device/600 microns; an 0805 device/2 mm; a 2010 device/5 mm; a 2512 device/6.35 mm) and the like. A package spacing may be associated with a spacing of a three terminal device (e.g., an SOT-223, an SOT-89, an SOT-723, an SOT-883, and the like). A package spacing may be associated with a spacing of a five, six, or even eight terminal device (e.g., an SOT-23-5, an SOT23-6, an SOT-23-8). A package spacing may be associated with a device having even higher pin counts (e.g., a dual in-line package, such as a SOIC, a TSOP, an SSOP, a TSSOP, a VSOP, and the like). A package spacing may be associated with a quad in-line package (e.g., a PLCC, a QFP, a TQFP, an LCC, an MLP, and the like). A package spacing may be associated with a grid array (e.g., a PGA, BGA, LGA, LFBGA, TFBGA, CGA, pBGA, LLP, and the like). A package spacing may be associated with a system on chip (SOC), system in package (SIP), chip on board (COB), chip on flex (COF), chip on glass (COG) and the like.

Certain applications may not have a practical restriction on a height of a device. Certain applications may have a specified maximum height of a device (e.g., in a direction normal to a surface to which the device may be attached). Device 300 may include a height 380, which may be chosen to be below a specified maximum height (if one exists). In some embodiments, 2, 5, 10, 20, 50, 100, or even 1000 layers may be used to create a multilayer stack. Gaps 330, 332, 334, and 336 include gap widths (normal to the page in FIG. 3); these gap widths may be the same or different lengths. The integrated gap width (or, the sum of the individual gap widths) may be greater than 50% of the package spacing. In some cases, the gap width (which may include the integrated gap width) may be greater than the package spacing, more than twice the package spacing, more than five times the package spacing, more than ten times the package spacing, or even more than fifty times the package spacing.

FIG. 4 illustrates a multilayer stack, according to some embodiments. Device 400 may include VSDM 120 and 122. VSDM 120 and 122 may be the same VSDM or different VSDM (e.g., having different compositions, fractions of various phases, clamp, trigger, and/or switching voltages, and the like). VSDM layers may be disposed on dielectric substrates. In the example shown in FIG. 4, device 400 may include a plurality of dielectric substrates 202, 204, and 206, which may be different or the same type of substrate.

VSDM 120 may connect pads 410 and 412 across gap 430. VSDM 122 may connect pads 420 and 422 across gap 432. Gaps in a multilayer stack (e.g., gaps 430 and 432) may have the same or different lengths.

Conductive pads 410 and 420 may be electrically connected. In this example, these pads are connected by via 350 through the multilayer stack. Via 350 may connect to a conductive lead 360. Similarly, conductive pads 412 and 422 may be connected by via 352 to conductive lead 362. Leads 360 and 362 may be separated by a package spacing 470, and a height of device 400 may be described by height 480.

Device 400 includes gaps 430 and 432 that are “vertically” oriented (e.g., the direction of the gap is parallel to vias 350 and 352). In some embodiments, a vertical gap may provide for an increased active volume. A gap width (normal to the page of FIG. 4) may be increased by increasing a number of layers (e.g., the number of discrete gaps) in a multilayer stack. Gap width may be increased by increasing the size of device 400 in a direction normal to the plane of FIG. 4 (e.g., increasing the contact area between the conductive pads and their respective VSDM.

FIG. 5 illustrates an exemplary embodiment. Device 500 includes VSDM 120. VSDM 120 may optionally be disposed on a substrate (not shown). Conductive leads 560 and 562 are each in electrical communication with a conductive pad (and/or a plurality of conductive pads), and are separated by package spacing 570. Lead 560 may be in communication with pad 510, and lead 562 may be in communication with pad 512. Pads 510 and 512 may be disposed on and connected by VSDM 120 across gap 530, and their arrangement may be described as an interdigitated comb (according to the “digits” of the respective pads). Gap width 550, which may be described as the “length” or “pathway” through the comb's digits, may be larger than 50% of package spacing 570, and in some embodiments may be much larger (e.g., five, ten, hundreds, or even thousands of times larger) than package spacing 570.

A multilayer stack may have individual layers having elongated gap widths (e.g., a plurality of stacked devices 500). Optional vias 350 and 352 may be used to connect conductive pads and leads on various layers in a multilayer stack.

FIG. 6 illustrates an exemplary embodiment. Device 600 may provide protection (e.g., against ESD damage) for a plurality of sites (e.g., several bond pads) on an electronic component. Device 600 may provide protection for a plurality of components (e.g., each connected to a conductive lead of device 600). Device 600 includes VSDM 120, which may optionally be disposed on a substrate. A conductive lead 660 (e.g., a lead that may be connected to ground) may be in electrical communication with a plurality of conductive pads 610, 620, 630, and 640 (described as “ground pads” for convenience). Each of a plurality of device leads 662, 664, 666, 668 may be in electrical communication with its respective conductive pad 612, 622, 632, and 642 (described as “device pads” for convenience).

The ground pads and device pads may be in contact with (e.g., disposed on) VSDM 120. VSDM 120 may connect the ground pad to a device pad across one or more gaps. Pads may be connected (via VSDM 120) across multiple gaps. A device pad may connect (via VSDM 120) to one or more ground pads, and a ground pad may connect (via VSDM 120) to one or more device pads. For example, current may flow between device pad 612 and ground pad 610 via VSDM across gaps 680, 682, and 684 (which may be the same or different distances). Device pad 622 may connect (via VSDM 120) to ground pad 620 across gap 690, and to ground pad 630 across gap 692. For clarity, only exemplary illustrative gaps are shown in FIG. 6.

Various leads may be separated according to one or more package spacings. For clarity, only exemplary package spacing 670 is illustrated, which describes a distance between device leads 664 and 666. In various embodiments, gap widths (and/or integrated or summed gap widths) may be greater than 50% of one or more package spacings. Some embodiments include a multilayer stack with one or more layers of device 600. Various gap widths (e.g., integrated gap widths) may be greater than 50% of at least one package spacing.

FIG. 7 illustrates an exemplary embodiment. Device 700 includes VSDM 120. VSDM 120 may optionally be disposed on a substrate (not shown). Conductive leads 760 and 762 are in electrical communication with conductive pads, and are separated by package spacing 770. Lead 760 may be in communication with pad 710, and lead 762 may be in communication with pad 712. Pads 710 and 712 may be disposed on and connected by VSDM 120 across one or more gaps. Exemplary gaps 730 and 732 are shown for illustrative purposes. Some embodiments include “curved” gaps, as shown in FIG. 7. Some embodiments include a multilayer stack with one or more layers of device 700. Various gap widths (e.g., integrated gap widths) may be greater than 50% of the package spacing. Gaps may be fabricated using lithography, electron-beam etching, selective deposition (e.g., atomic layer deposition on a silanated surface), chemical vapor deposition (which may be selective), physical vapor deposition (e.g., with a mask, photoresist, and the like), electrochemical deposition (which may include a seed layer), and the like.

FIG. 8 illustrates an exemplary embodiment. Device 800 includes VSDM 120, which may be disposed on a substrate. Device 800 includes first conductive pad 810 and second conductive pad 812, separated by gap 830. Device 800 may be characterized by a package spacing 870, which may describe a distance between portions of conductive pads 810 and 812 (e.g., bond sites associated with these pads, or via landing sites associated with these pads). For illustrative clarity, optional vias 350 and 352 may be used to define package spacing 870. During an ESD event, current may pass between conductive pads 810 and 812 through VSDM 120 via gap 830. Leads (not shown) may be connected to the conductive pads to connect the pads to a ground, component, and the like.

Device 800 includes an annular gap between inner pad 812 and outer (coaxial) pad 810. Certain embodiments include pads (connected by VSDM) having contact areas (to the VSDM) that are different. During an ESD event, current may flow between two pads having different contact areas, which may create a different current density at a first pad as compared to the second pad. Some embodiments include a pad having a higher current density (e.g., a smaller pad) connected to a component being protected. Some embodiments include a pad having a lower current density (e.g., a larger pad) connected to an electronic component being protected. A multilayer stack may include one or more devices 800. In some embodiments, gap width may be described by a coaxial circle associated with gap 830. Gap width may vary with position (e.g., with radius as in device 800). In some cases, at least a portion of the gap width of a device 800 may be greater than 50% of package spacing 870.

The use of the terminology “lead,” “pad,” “via,” and the like is for illustrative clarity only. These electrically conductive features may or may not be fabricated from different materials. These features may be substantially contiguous and/or interconnected discrete features.

Some embodiments include sensors to sense various parameters (e.g., thickness, strain, temperature, stress, viscosity, concentration, depth, length, width, thickness, number of layers, coefficient of thermal expansion (CTE), switching voltage and/or voltage density (between insulating and conducting), trigger voltage, clamp voltage, off-state current passage, dielectric constant, time, date, and other characteristics). Various apparatus may monitor various sensors, and systems may be actuated by automated controls (solenoid, pneumatic, piezoelectric, and the like). Some embodiments include a computer readable storage medium coupled to a processor and memory. Executable instructions stored on the computer readable storage medium may be executed by the processor to perform various methods described herein. Sensors and actuators may be coupled to the processor, providing input and receiving instructions associated with various methods. Certain instructions may provide for closed-loop control of various parameters via coupled sensors providing input and coupled actuators receiving instructions to adjust parameters. Certain embodiments include materials. Various embodiments may be associated with telephones (e.g., cell phones), USB-devices (e.g., a USB-storage device), personal digital assistants, iPods, iPads, laptop computers, netbook computers, tablet PC computers and the like.

The above description is illustrative and not restrictive. Many variations of the invention will become apparent to those of skill in the art upon review of this disclosure. The scope of the invention should, therefore, be determined not with reference to the above description, but instead should be determined with reference to the appended claims along with their full scope of equivalents.

Claims

1. A device incorporating a voltage switchable dielectric material (VSDM), the device comprising: first and second conductive leads separated by a package spacing; the first lead electrically connected to a first conductive pad;the second lead electrically connected to a second conductive pad;the first and second conductive pads separated by a first gap, the first gap having a first gap width greater than 50% of the package spacing;a first VSDM bridging the first gap and connecting the first and second conductive pads;a third conductive pad electrically connected to the first lead;a fourth conductive pad electrically connected to the second lead;the third and fourth conductive pads separated by a second gap; anda second VSDM connecting the first and second conductive pads via the second gap.

2. The device of claim 1, wherein the first gap width is greater than the package spacing.

3. The device of claim 1, wherein the first gap width is greater than two times the package spacing.

4. The device of claim 1, wherein the first gap width is greater than five times the package spacing.

5. The device of claim 1, wherein the first gap width is greater than ten times the package spacing.

6. The device of claim 1, wherein the second VSDM has a different composition than the first VSDM.

7. The device of claim 1, wherein the device includes a multilayer stack, the first and second VSDM are disposed on different layers of the multilayer stack, and the conductive pads are electrically connected to their respective leads by conductive vias through the multilayer stack.

8. The device of claim 1, wherein the first and second VSDM have different thicknesses.

9. The device of claim 1, wherein the first and second VSDM have different electrical properties.

10. The device of claim 1, wherein the first and second gaps have different gap widths.

11. The device of claim 1, wherein the first and second gaps have different lengths.

12. The device of claim 1, wherein the package spacing is between 200 microns and 8,000 microns.

13. The device of claim 1, wherein the package spacing corresponds to a distance between electrical connection points associated with any of an EIA 0201, 0402, and 0603 device.

14. The device of claim 1, wherein the first gap width is between 500 and 5000 microns.

15. The device of claim 1, wherein any of the pads, leads, and first gap is fabricated using lithography.

16. The device of claim 15, wherein the gap is characterized by a tolerance on a distance between the pads that is within 20% of the value of the distance.

17. The device of claim 16, wherein the tolerance is within 10%.

18. The device of claim 1, wherein the first gap is between 10 and 100 microns long.

19. The device of claim 1, further comprising a dielectric substrate, wherein the first VSDM is disposed as a first layer on the dielectric substrate and the first and second conductive pads are disposed as a second layer on the first VSDM.

20. The device of claim 19, wherein the substrate includes a layer of prepreg, and the conductive pads include copper.

21. The device of claim 1, further comprising a third conductive lead electrically connected to a fifth conductive pad, the fifth conductive pad attached to the first VSDM and separated from any of the first and second conductive pads by a third gap.

22. The device of claim 1, further comprising a fifth conductive pad attached to the first VSDM, the fifth conductive pad separated from any of the first and second conductive pads by a third gap, the fifth conductive pad electrically connected to either the first or second conductive lead.