Abstract: A semiconductor device includes a substrate comprising a heterostructure configured to support formation of a channel during operation, first and second dielectric layers supported by the substrate, the second dielectric layer being disposed between the first dielectric layer and the substrate, a gate supported by the substrate, disposed in a first opening in the first dielectric layer, and to which a bias voltage is applied during operation to control current flow through the channel, the second dielectric layer being disposed between the gate and the substrate, and an electrode supported by the substrate, disposed in a second opening in the first and second dielectric layers, and configured to establish a Schottky junction with the substrate.

Abstract: The present disclosure provides one embodiment of a semiconductor structure. The semiconductor structure includes a semiconductor substrate of a first semiconductor material; shallow trench isolation (STI) features formed in the semiconductor substrate; and a fin-like active region of a second semiconductor material epitaxy grown on the semiconductor substrate. The first semiconductor material has a first lattice constant and the second semiconductor material has a second lattice constant different from the first lattice constant. The fin-like active region further includes fluorine species.

Abstract: Methods of manufacturing device assemblies, as well as associated semiconductor assemblies, devices, systems are disclosed herein. In one embodiment, a method of forming a semiconductor device assembly includes forming a semiconductor device assembly that includes a handle substrate, a semiconductor structure having a first side and a second side opposite the first side, and an intermediary material between the semiconductor structure and the handle substrate. The method also includes removing material from the semiconductor structure to form an opening extending from the first side of the semiconductor structure to at least the intermediary material at the second side of the semiconductor structure. The method further includes removing at least a portion of the intermediary material through the opening in the semiconductor structure to undercut the second side of the semiconductor structure.

Abstract: In an exemplary implementation, a semiconductor device includes a drain pad on a semiconductor substrate, the drain pad being coupled to a plurality of drain fingers. The semiconductor device further includes a source pad on the semiconductor substrate, the source pad being coupled to a plurality of source fingers. The plurality of source fingers is interdigitated with the plurality of drain fingers. Furthermore, an outer corner of the drain pad has a gradual transition between adjoining sides of the drain pad. The gradual transition between the adjoining sides of the drain pad reduces a termination electric field at the outer corner of the drain pad. Furthermore, the gradual transition between the adjoining sides of the drain pad increases the breakdown voltage of the semiconductor device.

Abstract: A semiconductor structure with a MISFET and a HEMT region includes a first III-V compound layer. A second III-V compound layer is disposed on the first III-V compound layer and is different from the first III-V compound layer in composition. A third III-V compound layer is disposed on the second III-V compound layer is different from the second III-V compound layer in composition. A source feature and a drain feature are disposed in each of the MISFET and HEMT regions on the third III-V compound layer. A gate electrode is disposed over the second III-V compound layer between the source feature and the drain feature. A gate dielectric layer is disposed under the gate electrode in the MISFET region but above the top surface of the third III-V compound layer.

Abstract: Embodiments of a process including depositing a sacrificial layer on the surface of a substrate over a photosensitive region, over the top surface of a transfer gate, and over at least the sidewall of the transfer gate closest to the photosensitive region, the sacrificial layer having a selected thickness. A layer of photoresist is deposited over the sacrificial layer, which is patterned and etched to expose the surface of the substrate over the photosensitive region and at least part of the transfer gate top surface, leaving a sacrificial spacer on the sidewall of the transfer gate closest to the photosensitive region. The substrate is plasma doped to form a pinning layer between the photosensitive region and the surface of the substrate. The spacing between the pinning layer and the sidewall of the transfer gate substantially corresponds to a thickness of the sacrificial spacer. Other embodiments are disclosed and claimed.

Abstract: The present invention provides a CMOS compatible silicon differential condenser microphone and a method of manufacturing the same.

Abstract: A method for fabricating a MEMS device includes depositing and patterning a first sacrificial layer onto a silicon substrate, the first sacrificial layer being partially removed leaving a first remaining oxide. Further, the method includes depositing a conductive structure layer onto the silicon substrate, the conductive structure layer making physical contact with at least a portion of the silicon substrate. Further, a second sacrificial layer is formed on top of the conductive structure layer. Patterning and etching of the silicon substrate is performed stopping at the second sacrificial layer. Additionally, the MEMS substrate is bonded to a CMOS wafer, the CMOS wafer having formed thereupon a metal layer. An electrical connection is formed between the MEMS substrate and the metal layer.

Abstract: A finFET and methods for forming a finFET are disclosed. A structure comprises a substrate, a fin, a gate dielectric, and a gate electrode. The substrate comprises the fin. The fin has a major surface portion of a sidewall, and the major surface portion comprises at least one lattice shift. The at least one lattice shift comprises an inward or outward shift relative to a center of the fin. The gate dielectric is on the major surface portion of the sidewall. The gate electrode is on the gate dielectric.

Abstract: A method is provided for fabricating a fin field-effect transistor. The method includes providing a semiconductor substrate; and forming a plurality of fins on top of the semiconductor substrate. The method also includes forming isolation structures between adjacent fins; and forming doping sidewall spacers in top portions of the isolation structures near the fins. Further, the method includes forming a punch-through stop layer at the bottom of each of the fins by thermal annealing the doping sidewall spacers; and forming a high-K metal gate on each of the fins.

Abstract: A semiconductor device concerning an embodiment is provided with a semiconductor layer, an impurity-doped layer selectively formed on the semiconductor layer, and a drain electrode formed on the impurity-doped layer. The semiconductor device is further provided with a source electrode which is formed and isolated from the drain electrode, and a gate electrode which is formed between the source electrode and the drain electrode. The semiconductor device is provided with an insulating film which is formed between the gate electrode and the drain electrode, and a shielding plate which is formed on the insulating film and is electrically connected to the source electrode. At least a part of the shielding plate is formed above an extending portion of the impurity-doped layer which extends in the direction to the gate electrode from the drain electrode.

Abstract: Provided is a thin film transistor on fiber and a method of manufacturing the same. The thin film transistor includes a fiber; a first electrode, a second electrode and a gate electrode formed on fiber; a channel formed between the first and second electrodes; an encapsulant encapsulating the fiber, the first, second, and gate electrodes, and an upper surface of the channel; and a gate insulating layer formed in a portion of the inner area of the encapsulant.

Abstract: A nonplanar semiconductor device having a semiconductor body formed on an insulating layer of a substrate. The semiconductor body has a top surface opposite a bottom surface formed on the insulating layer and a pair of laterally opposite sidewalls wherein the distance between the laterally opposite sidewalls at the top surface is greater than at the bottom surface. A gate dielectric layer is formed on the top surface of the semiconductor body and on the sidewalls of the semiconductor body. A gate electrode is formed on the gate dielectric layer on the top surface and sidewalls of the semiconductor body. A pair of source/drain regions are formed in the semiconductor body on opposite sides of the gate electrode.

Abstract: A gate electrode (4) and a source electrode (5) of a semiconductor chip (3) are connected to a gate terminal (7) and a source terminal (9), respectively, via electric conductors (11a and 11b). A portion of the gate terminal (7) which portion is joined to the electric conductor (11a) is close to the gate electrode (4), and a portion of the source terminal (9) which portion is joined to the electric conductor (11b) is close to the source electrode (5).

Abstract: A semiconductor device, including: a gate electrode formed on a semiconductor substrate through a gate insulating film; an extension region formed in the semiconductor substrate on a source side of the gate electrode; a source region formed in the semiconductor substrate on the source side of the gate electrode through the extension region; an LDD region formed in the semiconductor substrate on a drain side of the gate electrode; and a drain region formed in the semiconductor substrate on the drain side of the gate electrode through the LDD region; wherein the extension region is formed at a higher concentration than that of the LDD region so as to be shallower than the LDD region.

Abstract: A CMOS image sensor with reduced crosstalk includes a semiconductor substrate formed with a plurality of photodiodes formed therein, a dielectric layer formed on the semiconductor substrate, a reflective layer formed on the dielectric layer, and an insulating layer formed on the reflective layer. A plurality of grooves is formed in the dielectric layer, the reflective layer, and the insulating layer above a corresponding photodiode. Each groove is filled with a color filter material to form a color filter above the photodiode. The image sensor also includes a planarization layer formed on the insulating layer and color filter. A microlens is formed on the planarizing layer. The light reflecting layer prevents stray light diffraction line crosstalk into an adjacent photodiode. The color filter grooves confine the target image light only through the filters in the groove window to reach the photodiode.

Abstract: An image sensor includes a substrate having a first surface opposing a second surface and a plurality of pixel regions. A photoelectric converter is included in each of the pixel regions, and a gate electrode is formed on the photoelectric converter. Also, a pixel isolation region isolates adjacent pixel regions. The pixel isolation region includes a first isolation layer coupled to a channel stop region. The channel stop region may include an impurity-doped region.

Abstract: An integrated circuit includes a semiconductor substrate, and an insulation region extending from a top surface of the semiconductor substrate into the semiconductor substrate. An Inter-Layer Dielectric (ILD) is overlying the insulation region. A capacitor includes a first capacitor plate including a first slot contact plug, and a second capacitor plate including a second slot contact plug. The first and the second contact plugs include portions in the ILD. A portion of the ILD between vertical surfaces of the first slot contact plug and the second slot contact plug acts as a capacitor insulator of the capacitor.

Abstract: Apparatus and methods for a MOS varactor structure are disclosed. An apparatus is provided, comprising an active area defined in a portion of a semiconductor substrate; a doped well region in the active area extending into the semiconductor substrate; at least two gate structures disposed in parallel over the doped well region; source and drain regions disposed in the well region formed on opposing sides of the gate structures; a gate connector formed in a first metal layer overlying the at least two gate structures and electrically coupling the at least two gate structures; source and drain connectors formed in a second metal layer and electrically coupled to the source and drain regions; and interlevel dielectric material separating the source and drain connectors in the second metal layer from the gate connector formed in the first metal layer. Methods for forming the structure are disclosed.

Abstract: A memory cell including a control gate located over a floating gate region. The floating gate region includes discrete doped semiconducting or conducting regions separated by an insulator and the discrete doped semiconducting or conducting regions have a generally cylindrical shape or a quasi-cylindrical shape.

Abstract: According to an embodiment, a non-volatile semiconductor storage device includes a silicon substrate including an active region isolated by an element isolation insulating film, a first insulating film formed on the active region, a charge accumulation layer formed on the first insulating film, a second insulating film formed on the charge accumulation layer, and a control gate formed on the second insulating film. A plane of the active region being in contact with the element isolation insulating film is a (100) plane or a plane inclining from the (100) plane by an inclination angle of 5° or less.

Abstract: The performances of a semiconductor device are improved. The semiconductor device has a first control gate electrode and a second control gate electrode spaced along the gate length direction, a first cap insulation film formed over the first control gate electrode, and a second cap insulation film formed over the second control gate electrode. Further, the semiconductor device has a first memory gate electrode arranged on the side of the first control gate electrode opposite to the second control gate electrode, and a second memory gate electrode arranged on the side of the second control gate electrode opposite to the first control gate electrode. The end at the top surface of the first cap insulation film on the second control gate electrode side is situated closer to the first memory gate electrode side than the side surface of the first control gate electrode on the second control gate electrode side.

Abstract: A semiconductor device including a first isolation region dividing a semiconductor substrate into first regions; memory cells each including a tunnel insulating film, a charge storing layer, an interelectrode insulating film, and a control gate electrode above the first region; a second isolation region dividing the substrate into second regions in a peripheral circuit region; and a peripheral circuit transistor including a gate insulating film and a gate electrode above the second region. The first isolation region includes a first trench, a first element isolation insulating film filled in a bottom portion of the first trench, and a first gap formed between the first element isolation insulating film and the interelectrode insulating film. The second isolation region includes a second trench and a second element isolation insulating film filled in the second trench. The first and the second element isolation insulating films have different properties.

Abstract: A discrete storage element film is disposed above a tunneling dielectric film against a shallow trench isolation structure and under conditions to resist formation of the discrete storage element film upon vertical exposures of the shallow trench isolation structure. A discrete storage element film is also disposed above a tunneling dielectric film against a recessed isolation structure. A microelectronic device incorporates the discrete storage element film. A computing system incorporates the microelectronic device.

Abstract: Provided is a memory device including a first dielectric layer, a T-shaped gate, two charge storage layers and two second dielectric layers. The first dielectric layer is disposed on a substrate. The T-shaped gate is disposed on the first dielectric layer and has an upper gate and a lower gate, wherein two gaps are present respectively at both sides of the lower gate and between the upper gate and the substrate. The charge storage layers are respectively embedded into the gaps. A second dielectric layer is disposed between each charge storage layer and the upper gate, between each charge storage layer and the lower gate and between each charge storage layer and the substrate.

Abstract: Methods for forming field effect transistors (FETs) with improved ON/OFF current ratios in addition to short charging times and the resulting devices are disclosed. Embodiments include forming a gate oxide layer above a channel region in a substrate, forming a partial self-adjusting threshold voltage layer above a drain-side end of the gate oxide layer, and forming a gate above the partial self-adjusting threshold voltage layer and the gate oxide layer.

Abstract: A split gate memory structure includes a pillar of active region having a first source/drain region disposed at a first end of the pillar, a second source/drain region disposed at a second end of the pillar, opposite the first end, and a channel region between the first and second source/drain regions. The pillar has a major surface extending between first and the second ends which exposes the first source/drain region, the channel region, and the second source/drain region. A select gate is adjacent the first source/drain region and a first portion of the channel region, wherein the select gate encircles the major surface the pillar. A charge storage layer is adjacent the second source/drain region and a second portion of the channel region, wherein the charge storage layer encircles the major surface the pillar. A control gate is adjacent the charge storage layer, wherein the control gate encircles the pillar.

Abstract: According to one embodiment, a semiconductor memory device includes a semiconductor member, a first insulating layer provided on the semiconductor member, a TaN layer provided on the first insulating layer and containing tantalum and nitrogen, a TaSiN layer provided on the TaN layer in contact with the TaN layer and containing tantalum, silicon, and nitrogen, a second insulating layer provided on the TaSiN layer in contact with the TaSiN layer and containing oxygen, and a control electrode provided on the second insulating layer.

Abstract: Memory cells including embedded SONOS based non-volatile memory (NVM) and MOS transistors and methods of forming the same are described. Generally, the method includes: forming a dielectric stack on a substrate, the dielectric stack including a tunneling dielectric on the substrate and a charge-trapping layer on the tunneling dielectric; patterning the dielectric stack to form a gate stack of a NVM transistor of a memory device in a first region of the substrate while concurrently removing the dielectric stack from a second region of the substrate; and performing a gate oxidation process of a baseline CMOS process flow to thermally grow a gate oxide of a MOS transistor overlying the substrate in the second region while concurrently growing a blocking oxide overlying the charge-trapping layer. In one embodiment, Indium is implanted to form a channel of the NVM transistor.

Abstract: A vertical memory device includes a channel array, a charge storage layer structure, multiple gate electrodes and a dummy pattern array. The channel array includes multiple channels, each of which is formed on a first region of a substrate and is formed to extend in a first direction substantially perpendicular to a top surface of the substrate. The charge storage layer structure includes a tunnel insulation layer pattern, a charge storage layer pattern and a blocking layer pattern, which are sequentially formed on a sidewall of each channel in the second direction substantially parallel to the top surface of the substrate. The gate electrodes arranged on a sidewall of the charge storage layer structure and spaced apart from each other in the first direction. The dummy pattern array includes multiple dummy patterns, each of which is formed on a second region adjacent the first region of the substrate and is formed to extend in the first direction.

Abstract: A memory device includes a plurality of channels, a plurality of first charge storage sites coupled to first sides of respective ones of the channels, and a plurality of second charge storage sites coupled to second sides of respective ones of the channels. The first charge storage sites correspond to first memory cells and the second charge storage sites coupled to second memory cells. At least one of the channels is a dummy channel not connected to a bit line, and a blocking layer is contiguously formed around the first and second charge storage sites and the channels.

Abstract: To enhance the performance of a semiconductor device. In a method for manufacturing a semiconductor device, a metal film is formed over a semiconductor substrate having an insulating film formed on a surface thereof, and then the metal film is removed in a memory cell region, whereas, in a part of a peripheral circuit region, the metal film is left. Next, a silicon film is formed over the semiconductor substrate, then the silicon film is patterned in the memory cell region, and, in the peripheral circuit region, the silicon film is left so that an outer peripheral portion of the remaining metal film is covered with the silicon film. Subsequently, in the peripheral circuit region, the silicon film, the metal film, and the insulating film are patterned for forming an insulating film portion formed of the insulating film, a metal film portion formed of the metal film, and a conductive film portion formed of the silicon film.

Abstract: In an MONOS-type memory cell with a split gate structure, short circuit between a selection gate electrode and a memory gate electrode is prevented, and reliability of a semiconductor device is improved. In a MONOS memory having a selection gate electrode and a memory gate electrode that are adjacent to each other and that extend in a first direction, an upper surface of the selection gate electrode in a region except for a shunt portion at an end portion of the selection gate electrode in the first direction is covered with a cap insulating film. The memory gate electrode is terminated on the cap insulating film side with respect to a border between the cap insulating film and an upper surface of the shunt portion exposed from the cap insulating film.

Abstract: A nonvolatile semiconductor memory device includes a semiconductor substrate, a first insulation layer formed on the semiconductor substrate, a charge storage layer formed on the first insulation layer, a second insulation layer formed on the charge storage layer, and a control electrode formed on the second insulation layer. The second insulation layer includes a first silicon oxide film formed above the charge storage layer, a silicon nitride film formed on the first silicon oxide film, a metal oxide film formed on the silicon nitride film, and a nitride film formed on the metal oxide film. The metal oxide film has a relative permittivity of not less than 7.

Abstract: A NAND flash memory unit is described, including a string of memory cells connected in series, S/D regions coupled to two terminals of the string, at least one select transistor couple between a terminal of the string and an S/D region, and at least one erase transistor couple between the at least one select transistor and an S/D region. The select transistor is for selecting the string of memory cells. The erase transistor is for reducing Vt-shift of the select transistor.

Abstract: An insulated gate field effect transistor configured to reduce the occurrence of a short-circuit fault, and a method of manufacturing the insulated gate field effect transistor are provided. A FET includes a semiconductor substrate, a gate insulator, a gate electrode, and a conductive member. The semiconductor substrate has an insulation groove that splits a channel region into a first channel region on a drain region side and a second channel region on a source region side. The conductive member is supported by a drain-side end face and a source-side end face of the insulation groove. When the temperature of the conductive member is equal to or higher than a predetermined temperature, the conductive member is cut.

Abstract: Aspects of the present disclosure describe a high density trench-based power MOSFETs with self-aligned source contacts and methods for making such devices. The source contacts are self-aligned with spacers and the active devices may have a two-step gate oxide. A lower portion may have a thickness that is larger than the thickness of an upper portion of the gate oxide. The MOSFETS also may include a depletable shield in a lower portion of the substrate. The depletable shield may be configured such that during a high drain bias the shield substantially depletes. It is emphasized that this abstract is provided to comply with rules requiring an abstract that will allow a searcher or other reader to quickly ascertain the subject matter of the technical disclosure. It is submitted with the understanding that it will not be used to interpret or limit the scope or meaning of the claims.

Abstract: Power wafer level chip scale package (CSP) and process of manufacture are enclosed. The power wafer level chip scale package includes all source, gate and drain electrodes located on one side of the device, which is convenient for mounting to a printed circuit board (PCB) with solder paste.

Abstract: A semiconductor device is provided which includes: semiconductor pillars which include impurity diffused layers, each semiconductor pillar having a width which allows full depletion of a semiconductor forming each semiconductor pillar, the impurity diffused layers being electrically connected to each other; and a common gate section which covers side faces of the pillars.

Abstract: A Field Effect Transistor (FET) and a method of manufacturing the same are provided. The FET may include a substrate; a source and a drain, one of which is formed on a bulge formed on a top surface of the substrate, and the other of which is formed in the substrate below but laterally offset from the bulge; a gate formed at a position where the bulge and the top surface of the substrate join each other; and a gate dielectric layer formed between the gate and the bulge and also between the gate and the top surface of the substrate. The FET has a vertical configuration, where the source is disposed on top of the bulge while the drain is disposed in the substrate, that is, the source and the drain are not in one same plane. As a result, the FET may have its area significantly reduced. Therefore, it is possible to improve an integration density of an IC and thus reduce cost.

Abstract: Power devices, and related process, where both gate and field plate trenches have multiple stepped widths, using self-aligned process steps.

Abstract: A MOS transistor structure comprises a substrate including a bulk semiconductor region, a first gate formed in a first trench, a first drain/source region, a second drain/source region, wherein the first drain/source region and the second drain/source region are formed on opposing sides of the first gate. The MOS transistor structure further comprises a second gate formed in a second trench, a third drain/source region, wherein the third drain/source region and the second drain/source region are formed on opposing sides of the second gate and a channel region formed in the bulk semiconductor region, wherein the channel region, the first drain/source region, the second drain/source region and the third drain source region share a same polarity.

Abstract: Aspects of the present disclosure describe a termination structure for a power MOSFET device. A termination trench may be formed into a semiconductor material and may encircle an active area of the MOSFET. The termination trench may comprise a first and second portion of conductive material. The first and second portions of conductive material are electrically isolated from each other. It is emphasized that this abstract is provided to comply with rules requiring an abstract that will allow a searcher or other reader to quickly ascertain the subject matter of the technical disclosure. It is submitted with the understanding that it will not be used to interpret or limit the scope or meaning of the claims.

Abstract: Semiconductor layers on active areas for transistors in a memory cell region (region A) and a peripheral circuit region (region B) are simultaneously epitaxially grown in the same thickness in which the adjacent semiconductor layers in region A do not come into contact with each other. Only semiconductor layer (10) in region B is also grown from the surface of a substrate which is exposed when only the surface of STI (2) in region B is drawn back, so that a facet (F) of the semiconductor layer 10 is formed outside the active area, followed by ion-implantation to form a high density diffusion layer (11) in region B. Accordingly, short circuit between semiconductor layers on source/drain electrodes of transistors in region A is prevented, and uniformity of the junction depth of the layer (11) of the source/drain electrodes including an ESD region in a transistor of region B is obtained, thereby restricting the short channel effect.

Abstract: A lateral device includes a gate region connected to a drain region by a drift layer. An insulation region adjoins the drift layer between the gate region and the drain region. Permanent charges are embedded in the insulation region, sufficient to cause inversion in the insulation region.

Abstract: An LDMOS is formed with a field plate over the n? drift region, coplanar with the gate stack, and having a higher work function than the gate stack. Embodiments include forming a first conductivity type well, having a source, surrounded by a second conductivity type well, having a drain, in a substrate, forming first and second coplanar gate stacks on the substrate over a portion of the first well and a portion of the second well, respectively, and tuning the work functions of the first and second gate stacks to obtain a higher work function for the second gate stack. Other embodiments include forming the first gate stack of a high-k metal gate and the second gate stack of a field plate on a gate oxide layer, forming the first and second gate stacks with different gate electrode materials on a common gate oxide, and forming the gate stacks separated from each other and with different gate dielectric materials.

Abstract: A technique for improving characteristics of a semiconductor device (DMOSFET) is provided. A semiconductor device is configured so as to include: an n-type source layer (102) disposed on an upper portion of a first surface side of an SiC substrate (106); a p body layer (103) which surrounds the source layer and has a channel region; an n?-type drift layer (107) which is in contact with the p body layer (103); a gate electrode (116) which is disposed on an upper portion of the channel region via a gate insulating film; and a first p+ layer (109) which is disposed in the p body layer (103), extends to a portion below the n+ source layer (102), and serves as a buried semiconductor region having an impurity concentration higher than that of the p body layer (103). In this manner, since the first p+ layer (109) is formed in the middle of the p body layer (103), it is possible to reduce the diffusion resistance of the p body layer (103). Thus, it is possible to make a parasitic bipolar transistor harder to turn on.

Abstract: A FinFET device and a method for fabricating a FinFET device is disclosed. An exemplary FinFET device includes a substrate including a fin structure, the fin structure including a first and a second fin. The FinFET device further includes a shallow trench isolation (STI) feature disposed on the substrate and between the first and the second fins. The FinFET device further includes a gate dielectric disposed on the first and the second fins. The FinFET device further includes a gate structure disposed on the gate dielectric. The gate structure traverses the first fin, the second fin, and the STI feature between the first fin and the second fin and has a longitudinal stepped profile.

Abstract: A method for forming a U-shaped semiconductor device includes forming trenches in a crystalline layer and epitaxially growing a U-shaped semiconductor material along sidewalls and bottoms of the trenches. The U-shaped semiconductor material is anchored, and the crystalline layer is removed. The U-shaped semiconductor material is supported by backfilling underneath the U-shaped semiconductor material with a dielectric material. A semiconductor device is formed with the U-shaped semiconductor material.

Abstract: A method for forming contacts in a semiconductor device includes forming a plurality of substantially parallel semiconductor fins on a dielectric layer of a substrate having a gate structure formed transversely to a longitudinal axis of the fins. The fins are merged by epitaxially growing a crystalline material between the fins. A field dielectric layer is deposited over the fins and the crystalline material. Trenches that run transversely to the longitudinal axis of the fins are formed to expose the fins in the trenches. An interface layer is formed over portions of the fins exposed in the trenches. Contact lines are formed in the trenches that contact a top surface of the interface layer on the fins and at least a portion of side surfaces of the interface layer on the fins.