Abstract: A method using a divided exposure technology is provided for restraining deterioration in the performance of a solid-state image sensor. A photoresist is formed over a semiconductor substrate and subjected to divided exposure. A dividing line for divided exposure is located at least over a region of a semiconductor substrate in which an active region in which a pixel is to be formed is defined. The photoresist is then developed and patterned. By utilizing the patterned photoresist, an element isolation structure for defining the active region in the semiconductor substrate is formed in the semiconductor substrate.

Abstract: Providing through-wafer interconnections in a semiconductor wafer includes forming a sacrificial membrane in a preexisting semiconductor wafer, depositing metallization over one side of the wafer so as to cover exposed portions of the sacrificial membrane facing the one side of the wafer, removing exposed portions of the sacrificial membrane facing the other side of the wafer, and depositing metallization over the other side of the wafer so as to contact the previously deposited metallization. Techniques also are disclosed for providing capacitive and other structures using thin metal membranes.

Abstract: An object is to provide a microstructure in which shear stress of a structural layer is increased, a manufacturing method thereof, and a microelectromechanical system. A sacrificial layer is formed over a substrate. A metal film is formed over the sacrificial layer. The metal film is irradiated with a laser beam. Needle-like crystals of the metal film are reduced or eliminated. The metal film is etched and processed into a predetermined shape to form a metal layer. Then, the sacrificial layer is removed. Accordingly, a microelectromechanical system which is excellent in reliability and in which a resistance property to breakage of a movable portion of the microstructure is improved can be provided.

Abstract: One aspect is a composite board including semiconductor chips in semiconductor device positions and a plastic housing composition partly embedding the semiconductor chips. A mould is provided for surrounding the semiconductor chips with plastic housing composition, the mould having a lower part and an upper part and a moldings cavity and the molding cavity having an upper contact area, which forms an interface with the top side of the plastic housing composition to be applied. The upper contact area is covered with a parting layer having essentially the same surface constitution and the same thermal conductivity as an adhesive film forming an interface with the underside of the plastic housing composition, with the result that a warpage of the composite board of less than 1% is obtained.

Abstract: This invention comprises manufacture of photovoltaic cells by deposition of thin film photovoltaic junctions on metal foil substrates. The photovoltaic junctions may be heat treated if appropriate following deposition in a continuous fashion without deterioration of the metal support structure. In a separate operation, an interconnection substrate structure is provided, optionally in a continuous fashion. Multiple photovoltaic cells are then laminated to the interconnection substrate structure and conductive joining methods are employed to complete the array. In this way the interconnection substrate structure can be uniquely formulated from polymer-based materials employing optimal processing unique to polymeric materials. Furthermore, the photovoltaic junction and its metal foil support can be produced in bulk without the need to use the expensive and intricate material removal operations currently taught in the art to achieve series interconnections.

Abstract: A method for forming a light-transmitting region comprises providing a support feature. A sacrificial layer is formed over a portion of the support feature, wherein the sacrificial layer comprises an energy-induced swelling material. A light-blocking layer is conformably formed over the support feature to cover the sacrificial layer and the support feature. The support feature, the sacrificial layer, and the light-blocking layer are subjected to an energy source to swell the sacrificial layer until bursting to thereby delaminate a portion of the light-blocking layer from the support feature and leave a light-transmitting region exposed with a portion of the support feature in the light-blocking layer. A gas flow or scrub cleaning force is provided to clean up the light-transmitting region and a top surface of the light-blocking layer remains over the support feature.

Abstract: A photodiode of a CMOS image sensor and a method for manufacturing the same are provided, in which ions implanted in the vicinity of a device isolation film are prevented from being diffused into a photodiode region to reduce a dark current. The photodiode of a CMOS image sensor includes a heavily doped P-type semiconductor substrate, a lightly doped P-type epitaxial layer formed on the semiconductor substrate, a gate electrode formed on the epitaxial layer, a device isolation film and an N-type photodiode region formed in the epitaxial layer, an insulating film formed on the epitaxial layer to open a portion between the device isolation film and the photodiode region, and a heavily doped P-type diffusion region formed in the epitaxial layer between the device isolation film and the photodiode region.

Abstract: A method of fabricating a vertical CMOS image sensor is disclosed, to improve the integration with the decrease in size of pixel by minimizing the lateral diffusion, in which phosphorous and arsenic ions are implanted while controlling the dose and energy, the method including forming a first photodiode in a semiconductor substrate; forming a first epitaxial layer on the semiconductor substrate; forming a first plug by sequentially implanting first and second ions in the first epitaxial layer; forming a second photodiode in the first epitaxial layer; forming a second epitaxial layer in the first epitaxial layer; forming an isolation area in the second epitaxial layer; and forming a third photodiode and a second plug in the second epitaxial layer.

Abstract: Isolation methods and devices for isolating regions of a semiconductor device. The isolation method and structure include forming an isolating trench in an active area and filling the trench with a doped conductive material containing silicon. Suitable conductive materials containing silicon include polysilicon and silicon-germanium. There is also provided a method and structure for isolating the regions by providing a trench in an active area of a substrate, growing an epitaxial layer in the trench to fill the trench or to partially fill the trench and depositing an insulating material over the epitaxial layer and within the trench to completely fill the trench.

Abstract: In view of the problem that an organic semiconductor layer of an organic TFT is likely to deteriorate due to water, light, oxygen, or the like, it is an object of the present invention to simplify a manufacturing step and to provide a method for manufacturing a semiconductor device having an organic TFT with high reliability. According to the invention, a semiconductor layer containing an organic material is formed by patterning using a mask, and thus an organic TFT is completed in the state where the mask is not removed but to remain over the semiconductor layer. In addition, a semiconductor layer can be protected from deterioration due to water, light, oxygen, or the like by using the remaining mask.

Abstract: Disclosed is a method for manufacturing an organic EL light emitting display device, comprising forming an anode electrode above a substrate, forming an organic light emitting layer above the anode electrode, performing a fluorinating treatment on a surface of the organic light emitting layer, and forming a cathode electrode directly on the fluorinated surface of the organic light emitting layer.

Abstract: A method of forming a structure in a phase changeable memory cell can include forming a bottom electrode having an interlayer dielectric layer thereon, the bottom electrode having a recess therein that extends beyond a boundary between the bottom electrode and the interlayer dielectric. A phase changeable layer can be formed in the recess including a protruding potion of the phase changeable layer that protrudes into the bottom electrode beyond the boundary.

Abstract: One exemplary embodiment includes a semiconductor device. The semiconductor device can include a channel including one or more of a metal oxide including zinc-gallium, cadmium-gallium, cadmium-indium.

Abstract: The present invention provides a multi-chip package system that includes: providing a package substrate; attaching a base semiconductor die to the package substrate; connecting an interconnect between the base semiconductor die and the package substrate; and encapsulating at least portions of the package substrate, the base semiconductor die, and the interconnect with an encapsulant defining a support protrusion adjacent to the interconnect and substantially perpendicular to the package substrate, a cavity bounded by the support protrusion, and a gap linking the cavity to the edge of the encapsulant.

Abstract: The present invention provides a unique way of connecting a flip-chip die to a substrate. Initially, metallic posts are formed on the flip-chip die and solder bumps are placed on the substrate where the metallic post will ultimately connect to the substrate. The tip layer of flash gold, tin, or other wettable electroplated material is applied to the tips of the metallic posts to prevent oxidation and enhance wettability. The sides of the metallic posts are allowed to oxidize to reduce wettability. To attach the flip-chip die to the substrate, the flip-chip die is initially positioned over the substrate, such that the metallic posts align with and come into contact with the solder bumps. Once the flip-chip die is in place over the substrate, the substrate and the flip-chip are heated to cause the solder bumps to reflow and bond to the tip layers of the metallic posts.

Abstract: A semiconductor multi-package module having stacked second and first packages, each package including a die attached to a substrate, in which the first and second package substrates are interconnected by wire bonding, and in which the first package is a flip chip ball grid array package in a die-up configuration. Also, a method for making a semiconductor multi-package module, by providing a first package including a first package substrate and having a die-up flip chip configuration, affixing a second package including a second package substrate an upper surface of the first package, and forming z-interconnects between the first and second package substrates.

Abstract: In a flip shop mounting method by a no-flow underfill in which resin is pre-coated on a substrate 52, and, thereafter, a semiconductor 50 with bump is mounted on the substrate 52 to join a pad electrode 53 on the substrate 52 to the bump 51, a resin 54a highly filed with the filler 55 is applied to a region except for the pad electrode 53 on the substrate 52, a resin 54b being free from the filler is applied to a pad electrode 53 portion on the substrate 52, and, thereafter, the semiconductor 50 with bump is mounted at a predetermined position on the substrate 52.

Abstract: A method of fabrication a non-volatile memory is provided. A stacked structure is formed on a substrate, the stacked structure including a gate dielectric layer and a control gate. Then, a first dielectric layer, a second dielectric layer and a third dielectric layer are respectively formed on the top and sidewalls of the stacked structure and the exposed substrate. Thereafter, a pair of charge storage layers are formed over the substrate to respectively cover a portion of the top and sidewalls of the stacked structure, and a gap exists between each of the charge storage layers.

Abstract: A semiconductor device and a fabricating method thereof are provided. The semiconductor device can include a first chip having transistors of only the NMOS type, a second chip having transistors of only the PMOS type, and an interconnection electrically connecting the first and second chips to each other. By forming NMOS and PMOS transistors on separate chips, the total number of implant photo processes can be decreased, thereby reducing the fabrication cost.

Abstract: A lead frame and a method of fabricating a semiconductor package including the lead frame, where the lead frame includes a die pad, a tie bar supporting the die pad, and a plurality of leads. The leads may include inner and outer leads arranged along an outer periphery of the die pad, with each of the inner and outer leads having tip terminals. The lead frame may include a connecting bar connected to tip terminals of each of the inner leads. In the method, a bonding pad of a semiconductor chip is mounted on the die pad and connected via a conductive wire to the inner leads of the lead frame. The semiconductor chip, wire and inner leads may be subjected to a molding process, and the connecting bar which connects the tip terminals of the inner leads may be cut so as to independently separate each of the inner leads from the die pad.

Abstract: A method to assemble a non-leaded semiconductor package is disclosed. In one embodiment, a carrier tape is attached to a metal foil. A plurality of leadframes are formed in the metal foil, each leadframe including a die pad laterally surrounded by a plurality of contact leads. A semiconductor die, including an active surface with a plurality of die contact pads, is attached to each die attach pad and electrically connected to the leadframe by a plurality of bond wires connecting the die contact pads and the lead contact areas of the contact leads. A plurality of leadframes, each including a wire bonded semiconductor die, are encapsulated with mold material. The carrier tape is removed and the non-leaded semiconductor packages separated.

Abstract: A method and an apparatus for improving the delivery and filtering of power to a semiconductor device is disclosed by organizing out interconnects (pins, balls, pads or other interconnects) used to carry power in a striped configuration that shortens the conductive path required between a power source and a semiconductor device and that reduces the resistance of that conductive path.

Abstract: In a memory cell array on a main surface of a semiconductor substrate, a floating gate electrode for accumulating charges for information is arranged. The floating gate electrode is covered with a cap insulating film and a pattern of a first insulating film formed thereon. Further, over the entire main surface of the semiconductor substrate, a second insulating film is deposited so that it covers the pattern of the first insulating film and a gate electrode. The second insulating film is formed by a silicon nitride film formed by a plasma CVD method. The first insulating film is formed by a silicon nitride film formed by a low-pressure CVD method. By the provision of such a first insulating film, it is possible to suppress or prevent water or hydrogen ions from diffusing to the floating gate electrode, and therefore, the data retention characteristics of a flash memory can be improved.

Abstract: To provide a method for manufacturing a semiconductor device including a transfer step that is capable of controlling the adhesiveness of a substrate and an element-formed layer in the case of separating the element-formed layer including a semiconductor element or an integrated circuit formed over the substrate from the substrate and bonding it to another substrate. An adhesive agent made of a good adhesiveness material is formed between the semiconductor element or the integrated circuit comprising plural semiconductor elements formed over the substrate (a first substrate) and the substrate, and thus it is possible to prevent a semiconductor element from peeling off a substrate in manufacturing the semiconductor element, and further, to make it easier to separate the semiconductor element from the substrate by removing the adhesive agent after forming the semiconductor element.

Abstract: The present invention is to provide a semiconductor device that achieves high mechanical strength without reducing the circuit scale and that can prevent the data from being forged and altered illegally while suppressing the cost. The present invention discloses a semiconductor device typified by an ID chip that is formed from a semiconductor thin film including a first region with high crystallinity and a second region with the crystallinity inferior to the first region. Specifically, a TFT (thin film transistor) of a circuit requiring high-speed operation is formed by using the first region and a memory element for an identifying ROM is formed by using the second region.

Abstract: Methods for manufacturing thin film transistor arrays utilizing three steps of lithography and one step of laser ablation while the lithography procedure is used four to five times in conventional processes are disclosed. The use of the disclosed methods assists in improving throughput and saving of manufacturing cost.

Abstract: One embodiment of the present invention is a method for manufacturing a bottom gate type thin film transistor having a gate electrode, a gate insulating film, an oxide semiconductor active layer, a source electrode and a drain electrode on a flexible plastic substrate of a supporting substrate, the method including continuously forming the gate insulating film and the oxide semiconductor active layer on the flexible plastic substrate with the gate electrode inside a vacuum film formation chamber of a film formation apparatus, the apparatus being a type of winding up continuously the roll-shaped substrate, and the gate insulating film and the oxide semiconductor active layer formed without being exposed to air.

Abstract: A thin film array panel is provided, which includes: a plurality of signal lines including contact parts for contact with an external device; a plurality of thin film transistors connected to the signal lines; an insulating layer formed on the signal lines and the thin film transistors; and a plurality of pixel electrodes formed on the insulating layer and connected to the thin film transistors, wherein the insulating layer includes a contact portion disposed on the contact parts of the signal lines and having a thickness smaller than other portions and the contact portion of the insulating layer includes an inclined portion having an inclination angle smaller than about 45 degrees.

Abstract: A flat panel display device (FPD) and fabricating method thereof are disclosed, which reduce the number of masks during fabrication and prevent electro-chemical corrosion problems. In the FPD, a cell area and a pad area are defined on a substrate. A storage electrode traverses an active layer in parallel to a gate line. Source and drain regions of the active layer in the vicinity of both sides of a gate electrode are not formed below the storage electrode. An insulating interlayer over the substrate has first and second contact holes on the source and drain regions, respectively. A source electrode contacts the source region via a first contact hole and a drain electrode contacts the drain region via a second contact hole to directly contact a pixel electrode. A protective layer is disposed over the substrate including the pixel electrode.

Abstract: A method of manufacturing a display device to improve the quality of a polycrystal silicon upon dehydrogenating and polycrystallizing an amorphous silicon at the outside of a display region of a substrate, by forming a plurality of pixels having TFT devices using an amorphous silicon in the display region of the substrate, and forming a plurality of driving circuits having semiconductor devices using a polycrystal silicon at the outside of the display region, the method including irradiation of a first continuous oscillation laser only to the amorphous silicon in the region for forming the driving circuit and the peripheral region thereof to conduct dehydrogenation and then irradiation of a second continuous oscillation region only to the dehydrogenated region to polycrystallize the amorphous silicon, wherein the region to which the first continuous oscillation laser is irradiated is wider than the region to which the second continuous oscillation laser is irradiated.

Abstract: A method for forming an ultra shallow junction on a substrate is provided. In certain embodiments a method of forming an ultra shallow junction on a substrate is provided. The substrate is placed into a process chamber. A silicon carbon layer is deposited on the substrate. The silicon carbon layer is exposed to a dopant. The substrate is heated to a temperature greater than 950° C. so as to cause substantial annealing of the dopant within the silicon carbon layer. In certain embodiments the substrate is heated to a temperature between about 1000° C. and about 1100°. In certain embodiments the substrate is heated to a temperature between about 1030° C. and 1050° C. In certain embodiments, a structure having an abrupt p-n junction is provided.

Abstract: The present invention provides a semiconductor device having dual nitride liners, which provide an increased transverse stress state for at least one FET and methods for the manufacture of such a device. A first aspect of the invention provides a method for use in the manufacture of a semiconductor device comprising the steps of applying a first silicon nitride liner to the device and applying a second silicon nitride liner adjacent the first silicon nitride liner, wherein at least one of the first and second silicon nitride liners induces a transverse stress in a silicon channel beneath at least one of the first and second silicon nitride liner.

Abstract: According to this invention, there is provided a NAND-type semiconductor storage device including a semiconductor substrate, a semiconductor layer formed on the semiconductor substrate, a buried insulating film selectively formed between the semiconductor substrate and the semiconductor layer in a memory transistor formation region, diffusion layers formed on the semiconductor layer in the memory transistor formation region, floating body regions between the diffusion layers, a first insulating film formed on each of the floating body regions, a floating gate electrode formed on the first insulating film, a control electrode on a second insulating film formed on the floating gate electrode, and contact plugs connected to ones of the pairs of diffusion layers which are respectively located at ends of the memory transistor formation region, wherein the ones of the pairs of diffusion layers, which are located at the ends of the memory transistor formation region, are connected to the semiconductor substrate belo

Abstract: A method of manufacturing a semiconductor device includes a process of forming a gate electrode having a metallic silicide layer on a semiconductor substrate, a process of decreasing boundaries of grains on the surface of the metallic silicide layer, at least a portion of which is exposed, and a process of forming spacers comprising an oxide film on the side wall of the gate electrode; in this order. Thus, abnormal oxidation of the metallic silicide layer is avoided.

Abstract: A manufacturing method of a semiconductor device having a highly reliable capacitor, and the semiconductor device are provided.

Abstract: A semiconductor process and apparatus provide a high voltage deep trench capacitor structure (10) that is integrated in an integrated circuit, alone or in alignment with a fringe capacitor (5). The deep trench capacitor structure is constructed from a first capacitor plate (4) that is formed from a doped n-type SOI semiconductor layer (e.g., 4a-c). The second capacitor plate (3) is formed from a doped p-type polysilicon layer (3a) that is tied to the underlying substrate (1).

Abstract: A string of nonvolatile memory cells connected in series includes fixed charges located between floating gates and the underlying substrate surface. Such a fixed charge affects distribution of charge carriers in an underlying portion of the substrate and thus affects threshold voltage of a device. A fixed charge layer may extend over source/drain regions also.

Abstract: A method for fabricating a memory device with a self-aligned trap layer which is optimized for scaling is disclosed. In the present invention, a non-conformal film is deposited over the charge trapping layer to form a thick film on top of the core source/drain region and a pinch off and a void or a narrow channel at the top of the STI trench. An etch is performed on the non-conformal film to open pinch-off or widen the narrow channel in the non-conformal. The trapping layer is then completely or partially etched between the core cells. The non-conformal film is removed. And a top oxide is formed. The top oxide converts the remaining trap layer to oxide if the trapping layer is partially etched and thus isolate the trap layer.

Abstract: A semiconductor device according to an embodiment of the present invention includes: a semiconductor substrate; an isolation structure formed in a trench, formed in the semiconductor substrate, through a semiconductor oxide film; a floating gate formed on the semiconductor substrate between the isolation structures through an insulating film; a gate oxidation protection film formed on a side surface, on the isolation structure side, of the floating gate so that each of a part of a side surface and a bottom surface of the gate oxidation protection film contacts the insulating film; and a control gate formed on the floating gate through an inter-gate insulating film.

Abstract: A split gate memory cell has a select gate, a control gate, and a charge storage structure. The select gate includes a first portion located over the control gate and a second portion not located over the control gate. In one example, the first portion of the select gate has a sidewall aligned with a sidewall of the control gate and aligned with a sidewall of the charge storage structure. In one example, the control gate has a p-type conductivity. In one example, the gate can be programmed by a hot carrier injection operation and can be erased by a tunneling operation.

Abstract: Semiconductor devices with an improved overlay margin and methods of manufacturing the same are provided. In one aspect, a method includes forming a buried bit line in a substrate; forming an isolation layer in the substrate to define an active region, the isolation layer being parallel to the bit line without overlapping the bit line; and forming a gate line including a gate pattern and a conductive line by forming the gate pattern in the active region and forming a conductive line that extends at a right angle to the bit line across the active region and is electrically connected to the gate pattern disposed thereunder. The gate pattern and the conductive line can be integrally formed.

Abstract: A method of forming a semiconductor device having an offset spacer may include forming a gate electrode on a semiconductor substrate. An etch stop layer including a nitride may be formed on the entire surface of the semiconductor substrate having the gate electrode. First spacers may be formed on the sidewalls of the gate electrode. The first spacers may be formed of a material layer having an etch selectivity with respect to the etch stop layer. The etch stop layer may be exposed on the semiconductor substrate on both sides of the gate electrode. Lightly-doped drain (LDD) regions may be formed in the semiconductor substrate using the gate electrode and the first spacers as an ion implantation mask. Second spacers may be formed on the first spacers. Accordingly, a semiconductor device having an offset spacer may be provided.

Abstract: Methods for fabricating dual bit memory devices are provided. In an exemplary embodiment of the invention, a method for fabricating a dual bit memory device comprises forming a charge trapping layer overlying a substrate and etching an isolation opening through the charge trapping layer. An oxide layer is formed overlying the charge trapping layer and within the isolation opening. A control gate is fabricated overlying the isolation opening and portions of the charge trapping layer adjacent to the isolation opening. The oxide layer and the charge trapping layer are etched using the control gate as an etch mask and impurity dopants are implanted into the substrate using the control gate as an implantation mask.

Abstract: The transistor comprises a source and a drain separated by a lightly doped intermediate zone. The intermediate zone forms first and second junctions respectively with the source and with the drain. The transistor comprises a first gate to generate an electric field in the intermediate zone, on the same side as the first junction, and a second gate to generate an electric field in the intermediate zone, on the same side as the second junction.

Abstract: A method of fabricating a semiconductor device is provided. Spacers can be formed on adjacent gate structures and used as an ion implantation mask for forming source/drain regions. The spacers can include a nitride layer and an oxide layer. An etch stop layer can be provided between the gate structures, and the oxide layer can be removed from the spacers. A first oxide layer formed below the nitride layer can be protected from being etched away during removal of the oxide layer from the spacers by the etch stop layer. The etch stop layer and the first oxide layer can be removed, and an interlayer dielectric layer can be deposited.

Abstract: A method for fabricating a CMOS integrated circuit (IC) includes the step of providing a substrate having a semiconductor surface. A gate stack including a metal gate electrode on a metal including high-k dielectric layer is formed on the semiconductor surface. Dry etching is used to pattern the gate stack to define a patterned gate electrode stack having exposed sidewalls of the metal gate electrode. The dry etching forms post etch residuals some of which are deposited on the substrate. The substrate including the patterned gate electrode stack is exposed to a solution cleaning sequence including a first clean step including a first acid and a fluoride for removing at least a portion of the post etch residuals, wherein the first clean step has a high selectivity to avoid etching the exposed sidewalls of the metal gate electrode. A second clean after the first clean consists essentially of a fluoride which removes residual high-k material on the semiconductor surface.

Abstract: A method of forming a transistor with self-aligned source and drain extensions in close proximity to a gate dielectric layer of the transistor comprises forming a gate stack on a substrate, implanting a dopant into regions of the substrate adjacent to the gate stack, wherein the dopant increases the etch rate of the substrate and defines the location of the source and drain extensions, forming a pair of spacers on laterally opposite sides of the gate stack that are disposed atop the doped regions of the substrate, etching the doped regions of the substrate and portions of the substrate subjacent to the doped regions, wherein an etch rate of the doped regions is higher than an etch rate of the portions of the substrate subjacent to the doped regions, and depositing a silicon-based material in the etched portions of the substrate.

Abstract: A method for fabricating a semiconductor structure. The semiconductor structure comprises first and second source/drain regions; a channel region disposed between the first and second source/drain regions; a buried well region in physical contact with the channel region; and a buried barrier region being disposed between the buried well region and the first source/drain region and being disposed between the buried well region and the second source/drain region, wherein the buried barrier region is adapted for preventing current leakage and dopant diffusion between the buried well region and the first source/drain region and between the buried well region and the second source/drain region.

Abstract: A method of forming a body-tie. The method includes forming the body-tie during an STI scheme of an SOI process. During the STI scheme, a first trench is formed. The first trench stops before a buried oxide layer of the SOI substrate. The first trench may determine a height of body tie that is shared between at least two FETs. A second trench may also be formed within the first trench. The second trench stops in the SOI substrate. The second trench defines the location and shape of a body-tie. Once the location and shape of the body-tie are defined, an oxide is deposited above the body-tie. The deposited oxide prevents certain implants from entering the body tie. By preventing these implants, a source and a drain implant may be self-aligned to the source and drain areas without requiring the use of the photoresist mask to shield the body tie regions from the source and drain implant.

Abstract: A method for fabricating a semiconductor structure. The novel transistor structure comprises first and second source/drain (S/D) regions whose top surfaces are lower than a top surface of the channel region of the transistor structure. A semiconductor layer and a gate stack on the semiconductor layer are provided. The semiconductor layer includes (i) a channel region directly beneath the gate stack, and (ii) first and second semiconductor regions essentially not covered by the gate stack, and wherein the channel region is disposed between the first and second semiconductor regions. The first and second semiconductor regions are removed. Regions directly beneath the removed first and second semiconductor regions are removed so as to form first and second source/drain regions, respectively, such that top surfaces of the first and second source/drain regions are below a top surface of the channel region.