Abstract: The luminous element includes a luminescence lamination, a second transparent oxidative conducting layer and a composite conducting layer. The composite conducting layer includes first transparent oxidative conducting layer and a metal layer. The second transparent oxidative conducting layer is positioned between the metal layer and luminescence lamination the second transparent oxidative conducting layer forms good ohmic contact with the luminous element and with metal layer. Thus, the metal layer will not be influenced by interfusion so as to maintain good light transmissivity and raise luminous efficiency of luminous element.

Abstract: A method of fabricating an integrated circuit on a compound semiconductor III-V wafer including at least two different types of active devices by providing a substrate; growing a first epitaxial structure on the substrate; growing a second epitaxial structure on the first epitaxial structure; and processing the epitaxial structures to form different types of active devices, such as HBTs and FETs.

Abstract: Disclosed is a method of forming a heterojunction bipolar transistor (HBT), comprising depositing a first stack comprising an polysilicon layer (16) and a sacrificial layer (18) on a mono-crystalline silicon substrate surface (10); patterning the first stack to form a trench (22) extending to the substrate; depositing a silicon layer (24) over the resultant structure; depositing a silicon-germanium-carbon layer (26) over the resultant structure; selectively removing the silicon-germanium-carbon layer (26) from the sidewalls of the trench (22); depositing a boron-doped silicon-germanium-carbon layer (28) over the resultant structure; depositing a further silicon-germanium-carbon layer (30) over the resultant structure; depositing a boron-doped further silicon layer (32) over the resultant structure; forming dielectric spacers (34) on the sidewalls of the trench (22); filling the trench (22) with an emitter material (36); exposing polysilicon regions (16) outside the side walls of the trench by selectively remo

Abstract: A heterojunction bipolar transistor (HBT) device and system having electrostatic discharge ruggedness, and methods for making the same, are disclosed. An HBT device having electrostatic discharge ruggedness may include one or more emitter fingers including an emitter layer, a transition layer formed over the emitter layer, and an emitter cap layer formed over the transition layer.

Abstract: The invention suggests a transistor (21) comprising a source (24) and a drain (29) as well as a barrier region (27) located between the source and the drain. The barrier region is separated from the source and the drain by intrinsic or lowly doped regions (26, 28) of a semiconductor material. Potential barriers are formed at the interfaces of the barrier region and the intrinsic or lowly doped regions. A gate electrode (32) is provided in the vicinity of the potential barriers such that the effective height and/or width of the potential barriers can be modulated by applying an appropriate voltage to the gate electrode.

Abstract: An integrated circuit structure includes a well region of a first conductivity type, an emitter of a second conductivity type opposite the first conductivity type over the well region, a collector of the second conductivity type over the well region and substantially encircling the emitter, and a base contact of the first conductivity type over the well region. The base contact is horizontally spaced apart from the emitter by the collector. At least one conductive strip horizontally spaces the emitter, the collector, and the base contact apart from each other. A dielectric layer is directly under, and contacting, the at least one conductive strip.

Abstract: A heterojunction bipolar transistor comprising a substrate; a collector on the substrate; a base layer on the collector; an emitter layer on the base layer; the emitter layer comprising an upper emitter layer and a lower emitter layer between the upper emitter layer and base; the collector, base and emitter layers being npn or pnp doped respectively; characterized in that the lower emitter layer has a larger bandgap than the base layer and is AlxIn1-xP or GaxAl1-xP, x being in the range 0+ to 1.

Abstract: High frequency performance of (e.g., silicon) bipolar devices is improved by reducing the extrinsic base resistance Rbx. Emitter, base and collector regions are formed in or on a semiconductor substrate. The emitter contact has a portion that overhangs a portion of the extrinsic base contact, thereby forming a cave-like cavity between the overhanging portion of the emitter contact and the underlying regions of the extrinsic base contact. When the emitter contact and the extrinsic base contact are silicided, some of the metal atoms forming the silicide penetrate into the cavity so that the highly conductive silicided extrinsic base contact extends under the edge of the emitter contact closer to the base itself, thereby reducing Rbx. Smaller Rbx provides transistors with higher fMAX.

Abstract: A semiconductor device includes a lower substrate, a thin semiconductor layer and an insulating layer formed between the lower substrate and the semiconductor layer. An active transistor area is formed with a base formed along a surface of the semiconductor layer, an emitter region formed in the base, a buried collector in the thin semiconductor layer to contact the insulating layer, a collector contacting the buried collector, and emitter, collector and base contacts. The active transistor area is configured to operate at an emitter current at least in the order of mA (milli-ampere). An isolation trench extends through the semiconductor layer to the insulating layer and surrounds the active transistor area with a distance in the order of ?m (micron) from the active transistor area and with a space area of more than 50 ?m2 between the active transistor area and the isolation trench.

Abstract: Embodiments relate to a method for forming a wiring in a semiconductor device, that may include laminating a conductive layer for wiring formation on a semiconductor substrate, forming a photoresist layer pattern on the conductive layer, performing primary dry etching for the conductive layer after employing the photoresist layer pattern as a mask, thereby forming a wiring pattern, partially removing the photoresist layer pattern through secondary dry etching, thereby forming a passivation layer on a surface of the wiring pattern, performing tertiary dry etching for the wiring pattern and a diffusion barrier after employing the photoresist layer pattern as a mask, thereby forming a metal wiring, and removing the photoresist layer pattern.

Abstract: A bipolar transistor and a radio frequency amplifier circuit capable of preventing thermal runaway in the bipolar transistor without affecting the radio frequency amplifier circuit, which includes: a direct-current (DC) bias terminal to which a DC bias is supplied; a DC base electrode connected to the DC terminal; a radio frequency (RF) power terminal to which a radio frequency signal is supplied; an RF base electrode connected to the RF terminal; and a base layer connected to the DC base electrode and the RF base electrode.

Abstract: A method of manufacturing a bipolar transistor is compatible with FinFET processing. A collector region (18) is formed and patterned, base contact regions (26) formed on either side, and a gap formed between the base contact region. A base (28), spacers (30) and an emitter (32) are formed in the gap.

Abstract: Disclosed are embodiments of a method of fabricating a bipolar transistor with a self-aligned raised extrinsic base. In the method a dielectric pad is formed on a substrate with a minimum dimension capable of being produced using current state-of-the-are lithographic patterning. An opening is aligned above the dielectric pad and etched through an isolation oxide layer to an extrinsic base layer. The opening is equal to or greater in size than the dielectric pad. Another smaller opening is etched through the extrinsic base layer to the dielectric pad. A multi-step etching process is used to selectively remove the extrinsic base layer from the surfaces of the dielectric pad and then to selectively remove the dielectric pad. An emitter is then formed in the resulting trench. The resulting transistor structure has a distance between the edge of the lower section of the emitter and the edge of the extrinsic base that is minimized, thereby, reducing resistance.

Abstract: Disclosed are embodiments of a hetero-junction bipolar transistor (HBT) structure and method of forming the structure that provides substantially lower collector-to-base parasitic capacitance and collector resistance, while also lowering or maintaining base-to-emitter capacitance, emitter resistance and base resistance in order to achieve frequency capabilities in the THz range. The HBT is a collector-up HBT in which a dielectric layer and optional sidewall spacers separate the raised extrinsic base and the collector so as to reduce collector-to-base capacitance. A lower portion of the collector is single crystalline semiconductor so as to reduce collector resistance. The raised extrinsic base and the intrinsic base are stacked single crystalline epitaxial layers, where link-up is automatic and self-aligned, so as to reduce base resistance. The emitter is a heavily doped region below the top surface of a single crystalline semiconductor substrate so as to reduce emitter resistance.

Abstract: A thin-film crystal wafer having a pn junction includes a first crystal layer of p GaAs, a second crystal layer of n InxAlyGa1?x?yP, the first and second crystal layers being lattice-matched layers that form a heterojunction, and a control layer of a thin-film of InxAlyGa1?x?yP differing in composition from the n InxAlyGa1?x?yP of the second crystal layer is formed at the interface of the heterojunction. The control layer enables the energy discontinuity at the interface of the InxAlyGa1?x?yP/GaAs heterojunction to be set within a relatively broad range of values and thus enables the current amplification factor and the offset voltage to be matched to specification values by varying the energy band gap at the heterojunction.

Abstract: In a bipolar device, such as transistor or a thyristor, the emitter layer or the anode layer is formed of two high-doped and low-doped layers, a semiconductor region for suppressing recombination comprising an identical semiconductor having an impurity density identical with that of the low-doped layer is present being in contact with a base layer or a gate layer and a surface passivation layer, and the width of the semiconductor region for suppressing recombination is defined equal with or longer than the diffusion length of the carrier. This provides, among other things, an effect of attaining reduction in the size of the bipolar transistor or improvement of the switching frequency of the thyristor without deteriorating the performance.

Abstract: An integrated pair of HBT and FET transistors shares a common compound semiconductor III-V epitaxial layer. The integrated pair of transistors includes a semi-insulating substrate of a compound semiconductor III-V material, a first epitaxial structure disposed on top of the substrate, a second epitaxial structure on top of the first epitaxial structure, and a third epitaxial structure disposed on top of the second epitaxial structure. The first epitaxial structure forms a portion of the HBT transistor. A concentration profile of a first contaminant, which contributes electrical charge, decreases substantially smoothly across an interface between the semi-insulating substrate and the first epitaxial structure. In some cases, the interface is free of a second contaminant that was present, during formation of the epitaxial structures, in a chamber in which the epitaxial structures were formed.

Abstract: A bipolar junction transistor having an emitter, a base, and a collector includes a stack of one or more layer sets adjacent the collector. Each layer set includes a first material having a first band gap, wherein the first material is highly doped, and a second material having a second band gap narrower than the first band gap, wherein the second material is at most lightly doped.

Abstract: A system and method are disclosed for providing a self aligned silicon germanium (SiGe) heterojunction bipolar transistor using a mesa emitter-base architecture. The transistor of the present invention comprises a non-selective epitaxial growth (NSEG) collector, an NSEG base, an NSEG emitter and a raised external base that is formed by the selective epitaxial growth (SEG) of a doped polysilicon layer.

Abstract: A system and method are disclosed for providing an improved polyemit module for a self aligned heterojunction bipolar transistor architecture. The polyemit module of the transistor of the present invention is formed using a double layer deposition process. In the double layer deposition process, the first layer is a layer of emitter polysilicon and the second layer is a sacrificial layer of silicon germanium (SiGe). The shape and thickness of the emitter polysilicon layer of the polyemit module provides (1) a reduction in the overall resistance of the emitter and (2) an increase in the contact area between the emitter polysilicon layer and a contact structure that is more than three times the contact area that is provided in prior art polyemit modules.

Abstract: The present invention provides a layout for a self-aligned semiconductor device, comprising an emitter mesa structure having an emitter electrode, and a base region that is comprised of a base electrode, with the base electrode deposited along crystal planes of the emitter mesa structure that undercut when the emitter mesa structure is etched, while avoiding depositing of the base electrode along crystal planes of the emitter mesa structure that do not undercut when the emitter mesa structure is etched. This allows the emitter electrode and the base electrode to self-align along the crystal planes that the emitter mesa structure undercuts when etched, and be isolated along the crystal planes that the emitter mesa structure does not undercut when etched. The present invention further provides dual interconnects mechanism and for connecting external circuitry to various semiconductor layers.

Abstract: A thin film electron source comprising a substrate, a lower electrode formed on one main face of said substrate, an insulation layer formed in contact with said lower electrode and an upper electrode formed in contact with said insulation layer. The upper electrode comprises a first under-layer, a second under-layer, an intermediate layer and a surface layer laminated from the insulation layer side. A main material of the first under-layer is IrO2 or RuO2; a main material of the second under-layer is Ir or Ru, and a main material of the surface layer is a member selected from the group consisting of Au and Ag.

Abstract: A heterojunction bipolar transistor includes a first conductivity type subcollector layer, a first collector layer containing a first conductivity type impurity, a third collector layer containing a higher concentration of the first conductivity type impurity than the first collector layer, a second collector layer containing a lower concentration of the first conductivity type impurity than the first collector layer, a second conductivity type base layer, a first conductivity type emitter layer containing a semiconductor with a wider bandgap than the base layer, and a first conductivity type emitter cap layer.

Abstract: A heterojunction bipolar transistor with InGaP as the emitter layer and capable of both reliable electrical conduction and thermal stability wherein a GaAs layer is inserted between the InGaP emitter layer and AlGaAs ballast resistance layer, to prevent holes reverse-injected from the base layer from diffusing and reaching the AlGaAs ballast resistance layer.

Abstract: A transistor comprises a nanowire (22, 22?) having a source (24) and a drain (29) separated by an intrinsic or lowly doped region (26, 28). A potential barrier is formed at the interface of the intrinsic or lowly doped region (26, 28) and one of the source (24) and the drain (29). A gate electrode (32) is provided in the vicinity of the potential barrier such that the height of the potential barrier can be modulated by applying an appropriate voltage to the gate electrode (32).

Abstract: A method of fabricating a hetero-junction bipolar transistor (HBT) is disclosed, where the HBT has a structure incorporating a hetero-junction bipolar structure disposed on a substrate including of silicon crystalline orientation <110>. The hetero-junction bipolar structure may include an emitter, a base and a collector. The substrate may include a shallow-trench-isolation (STI) region and a deep trench region on which the collector is disposed. The substrate may include of a region of silicon crystalline orientation <100> in addition to silicon crystalline orientation <110> to form a composite substrate by using hybrid orientation technology (HOT). The region of crystalline orientation <100> may be disposed on crystalline orientation <110>. Alternatively, the region of silicon crystalline orientation <110> may be disposed on crystalline orientation <100>.

Abstract: In a nitride semiconductor based bipolar transistor, a contact layer formed so as to contact an emitter layer is composed of n-type InAlGaN quaternary mixed crystals, the emitter layer and the contact layer are selectively removed so that the barrier height with the emitter formed thereon is small, and the ohmic electrode contact resistance can be lowered on the InAlGaN quaternary mixed crystals, for example, so that a WSi emitter electrode becomes an eave. A base electrode is formed by a self-aligned process using the emitter electrode as a mask. By such a configuration, the distance between the emitter and the edge of the base electrode is sufficiently shortened, and the base resistance can be lowered. As a result, a bipolar transistor having favorable high-frequency characteristics can be realized.

Abstract: The object of the present invention is to provide a heterojunction bipolar transistor with high breakdown tolerance which can be manufactured at a high reproducibility and a high yield, the heterojunction bipolar transistor includes: a sub-collector layer; a collector layer formed on the sub-collector layer; a base layer formed on the collector layer; and an emitter layer, which is formed on the base layer and is made of a semiconductor that has a larger bandgap than a semiconductor of the base layer, in which the collector layer includes: a first collector layer formed on the sub-collector layer; a second collector layer formed on the first collector layer; and a third collector layer formed between the second collector layer and the base layer, a semiconductor of the first collector layer differs from semiconductors of the third collector layer and the second collector layer, and an impurity concentration of the second collector layer is lower than an impurity concentration of the sub-collector layer and hi

Abstract: A phototransistor includes an emitter and a base that comprises Ge. A collector comprises Si. The base, emitter, and collector form at least one Si/Ge heterojunction allowing the unpinning of Fermi energy level (EF) of the phototransistor.

Abstract: An integrated semiconductor cascode circuit is provided that comprises an emitter layer, a first base area, a second base area, an intermediate area and a collector area. The first base area is arranged between the emitter layer and the intermediate area, and the second base area is arranged between the intermediate area and the collector area. A dielectric layer that is provided with a central opening is arranged between the first base area and the second base area. The invention also relates to a method for the production of said semiconductor cascode circuit.

Abstract: A method for forming a germanium-enriched region in a heterojunction bipolar transistor and a heterojunction bipolar transistor comprising a germanium-enriched region. A base having a silicon-germanium portion is formed over a collector. Thermal oxidation of the base causes a germanium-enriched region to form on a surface of the silicon-germanium portion subjected to the thermal oxidation. An emitter is formed overlying the germanium-enriched portion region. The germanium-enriched region imparts advantageous operating properties to the heterojunction bipolar transistor, including improved high-frequency/high-speed operation.

Abstract: A lateral bipolar junction transistor having improved current gain and a method for forming the same are provided. The transistor includes a well region of a first conductivity type formed over a substrate, at least one emitter of a second conductivity type opposite the first conductivity type in the well region wherein each of the at least one emitters are interconnected, a plurality of collectors of the second conductivity type in the well region wherein the collectors are interconnected to each other, and a plurality of base contacts of the first conductivity type in the well region wherein the base contacts are interconnected to each other. Preferably, all sides of the at least one emitters are adjacent the collectors, and none of the base contacts are adjacent the sides of the emitters. The neighboring emitter, collectors and base contacts are separated by spacings in the well region.

Abstract: Provided are a hetero-junction bipolar transistor (HBT) that can increase data processing speed and a method of manufacturing the hetero-junction bipolar transistor.

Abstract: A semiconductor device including a horizontal unit semiconductor element, the horizontal unit semiconductor element including: a) a semiconductor substrate of a first conductivity type; b) a semiconductor region of a second conductivity type formed on the semiconductor substrate; c) a collector layer of the first conductivity type formed within the semiconductor region; d) a base layer of the first conductivity type having an endless shape and formed within the semiconductor region such that the base layer is off the collector layer but surrounds the collector layer; and e) a first emitter layer of the second conductivity type formed in the base layer, the horizontal unit semiconductor element controlling, within a channel region formed in the base layer, movement of carriers between the first emitter layer and the collector layer, wherein the first emitter layer is formed by plural unit emitter layers which are formed along the base layer.

Abstract: A transistor having minimized parasitics is provided including an emitter having a recessed extrinsic emitter portion atop an intrinsic emitter portion; a base including an intrinsic base portion in electrical contact with the intrinsic emitter portion and an extrinsic base portion in electrical contact with the intrinsic base portion and electrically isolated from the recessed extrinsic emitter portion by a set of emitter/base spacers; and a collector in electrical contact with the intrinsic base portion. The transistor may further include extrinsic base having top surfaces entirely silicided to the emitter/base spacer. Additionally, the transistor may include a base window opening within the transistor's active area. Methods of forming the above-described transistor are also provided.

Abstract: Provided is a process for forming a contact for a compound semiconductor device without electrically shorting the device. In one embodiment, a highly doped compound semiconductor material is electrically connected to a compound semiconductor material of the, same conductivity type through an opening in a compound semiconductor material of the opposite conductivity type. Another embodiment discloses a transistor including multiple compound semiconductor layers where a highly doped compound semiconductor material is electrically connected to a compound semiconductor layer of the same conductivity type through an opening in a compound semiconductor layer of the opposite conductivity type. Embodiments further include metal contacts electrically connected to the highly doped compound semiconductor material. A substantially planar semiconductor device is disclosed. In embodiments, the compound semiconductor material may be silicon carbide.

Abstract: A semiconductor component has a semiconductor body (100) having a basic doping and a first and second side, an inner region (103) arranged between the first and second sides, and an edge region (104) adjacent to the inner region in a lateral direction, at least one active component zone (12) which is arranged in the inner region (103) in the region of the first side (101) and is doped complementarily to the basic doping, and a channel stop zone (20), which is arranged in the edge region (104) in the region of the first side (101), is of the same conduction type as the basic doping and is doped more heavily than the basic doping, the doping concentration in the channel stop zone (20) decreasing continuously at least in sections in a lateral direction in the direction of the active component zone (12) at least over a distance (d1) of 10 ?m.

Abstract: A heterojunction bipolar transistor (HBT) device and system having electrostatic discharge ruggedness, and methods for making the same, are disclosed. An HBT device having electrostatic discharge ruggedness may include one or more emitter fingers including an emitter layer, a transition layer formed over the emitter layer, and an emitter cap layer formed over the transition layer.

Abstract: A method of managing radiation having a frequency in the terahertz and/or microwave regions. The method comprises providing a semiconducting device having a two-dimensional carrier gas. Plasma waves are generated in the carrier gas using a laser pulse. The frequency of the plasma waves, and as a result, the generated radiation are adjusted using a voltage applied to the semiconducting device.

Abstract: Disclosed are apparatus and methods for designing electrical contact for a bipolar emitter structure. The area of an emitter structure (106, 306, 400, 404) and the required current density throughput of an electrical contact structure (108, 308, 402, 406) are determined. A required electrical contact area is determined based on the required current density, and the electrical contact structure is then designed to minimize the required electrical contact area with respect to the emitter structure area.

Abstract: A bipolar transistor having a base region resting by its lower surface on a collector region and surrounded with a first insulating layer, a base contact conductive region in contact with an external upper peripheral region of the base region, a second insulating region in contact with an intermediary upper peripheral region of the base region, an emitter region in contact with the central portion of the base region. The level of the central portion is higher than the level of the intermediary portion.

Abstract: A heterojunction bipolar transistor: The transistor may a collector layer, a base layer and an emitter layer. The transistor may include a dielectric material being disposed over the base layer. The base layer may be a SiGe base layer.

Abstract: The semiconductor device of this invention includes an active region formed from a group III nitride semiconductor grown on a substrate and an insulating oxide film formed in a peripheral portion of the active region by oxidizing the group III nitride semiconductor. On the active region, a gate electrode in Schottky contact with the active region extending onto the insulating oxide film and having an extended portion on the insulating oxide film is formed, and ohmic electrodes respectively serving as a source electrode and a drain electrode are formed with space from side edges along the gate length direction of the gate electrode.

Abstract: The HBT-based transient suppression device contains a collector layer of a first conduction type, a base layer of a second conduction type, an emitter layer of the first conduction type, stacked in this order sequentially on a top side of a heavily doped substrate of the first conduction type. The doping concentration of the base layer is higher than that of the emitter and collector layers, and that the thickness of the collector layer is less than 300 nm, so that the BVCEO breakdown voltage is reduced below 5V Additionally, the thickness of the base layer is larger than the sum of the thickness of a section of the emitter-base depletion region extending into the base layer and the thickness of a section of the base-collector depletion region extending into the base layer, so that the base layer is not operated in a punch-through condition.

Abstract: Bipolar junction transistors (BJTs) and single or double heterojunction bipolar transistors with low parasitics, and methods for making the same is presented. A transistor is fabricated such that the collector region underneath a base contact area is deactivated. This results in a drastic reduction of the base-collector parasitic capacitance, Cbc. An embodiment of the present invention provides a transistor architecture for which the base contact area can be decoupled from the collector and hence allows for dramatic reduction in the parasitics of transistors.

Abstract: A method for forming an epitaxial base layer in a bipolar device. The method comprises the steps of: providing a structure having a field isolation oxide region (12) adjacent to an active silicon region (10); forming a silicon nitride/silicon stack (14, 16) above the field isolation oxide region (12), wherein the silicon nitride/silicon stack (14, 16) includes a top layer of silicon (14) and a bottom layer of silicon nitride (16); performing an etch to the silicon nitride/silicon stack (14, 16) to form a stepped seed layer, wherein the top layer of silicon is etched laterally at the same time the bottom layer of silicon nitride is etched; and growing an Si/SiGe/Si stack (20) over the stepped seed layer and active region (10).

Abstract: Disclosed are an improved hetero-junction bipolar transistor (HBT) structure and a method of forming the structure that incorporates a silicon-germanium emitter layer with a graded germanium profile. The graded germanium concentration creates a quasi-drift field in the neutral region of the emitter layer. This quasi-drift field induces valence bandgap grading within the emitter layer so as to accelerate movement of holes from the base layer through the emitter layer. Accelerated movement of the holes from the base layer through the emitter layer reduces emitter delay time and thereby, increases the cut-off frequency (fT) and the maximum oscillation frequency (fMAX) of the resultant HBT.

Abstract: A compound semiconductor epitaxial substrate including a substrate, and a sub-collector layer, a collector layer, a base layer, an emitter layer and a contact layer(s) formed in this order on the substrate, the compound semiconductor epitaxial substrate having an oxygen-containing layer between the substrate and the sub-collector layer.

Abstract: A transistor having minimized parasitics is provided including an emitter having a recessed extrinsic emitter portion atop an intrinsic emitter portion; a base including an intrinsic base portion in electrical contact with the intrinsic emitter portion and an extrinsic base portion in electrical contact with the intrinsic base portion and electrically isolated from the recessed extrinsic emitter portion by a set of emitter/base spacers; and a collector in electrical contact with the intrinsic base portion. The transistor may further include extrinsic base having top surfaces entirely silicided to the emitter/base spacer. Additionally, the transistor may include a base window opening within the transistor's active area. Methods of forming the above-described transistor are also provided.

Abstract: Provided is a process for forming a contact for a compound semiconductor device without electrically shorting the device. In one embodiment, a highly doped compound semiconductor material is electrically connected to a compound semiconductor material of the same conductivity type through an opening in a compound semiconductor material of the opposite conductivity type. Another embodiment discloses a transistor including multiple compound semiconductor layers where a highly doped compound semiconductor material is electrically connected to a compound semiconductor layer of the same conductivity type through an opening in a compound semiconductor layer of the opposite conductivity type. Embodiments further include metal contacts electrically connected to the highly doped compound semiconductor material. A substantially planar semiconductor device is disclosed. In embodiments, the compound semiconductor material may be silicon carbide.