Abstract: A manufacturing method is provided which achieves an SOI substrate with a large area and can improve productivity of manufacture of a display device using the SOI substrate. A plurality of single-crystalline semiconductor layers are bonded to a substrate having an insulating surface, and a circuit including a transistor is formed using the single-crystalline semiconductor layers, so that a display device is manufactured. Single-crystalline semiconductor layers separated from a single-crystalline semiconductor substrate are applied to the plurality of single-crystalline semiconductor layers. Each of the single-crystalline semiconductor layers has a size corresponding to one display panel (panel size).

Abstract: The present invention relates to fabrication of enhancement mode and depletion mode High Electron Mobility Field Effect Transistors on the same die separated by as little as 10 nm. The fabrication method uses selective decomposition and selective regrowth of the Barrier layer and the Cap layer to engineer the bandgap of a region on a die to form an enhancement mode region. In these regions zero or more devices may be fabricated.

Abstract: An integrated circuit fabricated on a semiconductor-on-insulator transferred layer is described. The integrated circuit includes an interconnect layer fabricated on the back side of the insulator. This interconnect layer connects active devices to each other through holes etched in the insulator. This structure provides extra layout flexibility and lower capacitance, thus enabling higher speed and lower cost integrated circuits.

Abstract: A transistor includes a semiconductor substrate includes having a gate hardmask over the gate electrode layer during the formation of transistor source/drain regions. An independent work function adjustment process implants Group IIIa series dopants into a gate polysilicon layer of a PMOS transistor and implants lanthanide series dopants into a gate polysilicon layer of a NMOS transistor.

Abstract: A method for fabricating a semiconductor structure includes providing a semiconductor substrate having a first region and a second region, and doping top of the semiconductor substrate to form a doped layer at top surface of the semiconductor substrate over the first region and the second region. The method also includes etching the doped layer to form a first sub-fin in the first region and a first sub-fin in the second region, and forming an insulating layer over the semiconductor substrate including the first sub-fin in the first region and the first sub-fin in the second region. Further, the method includes removing top portions of the first sub-fin in the first region and the first sub-fin in the second region and forming corresponding second sub-fins.

Abstract: A semiconductor device including contact holes and method for forming the same are provided. A dual-stress liner is formed on a substrate. A first, second and third dielectric layers are then formed over the dual-stress liner. The second dielectric layer has a top surface leveling with that of an overlapping portion of the dual-stress liner. The third dielectric layer is etched to form first openings to have the etching stop at the second dielectric layer and at the upper stress liner of the overlapping portion. The second dielectric layer, the first dielectric layer and the upper stress liner are etched along the first openings to form second openings having the etching stop at the lower stress liner of the overlapping portion and the dual-stress liner in other regions. The stress liners are etched to form contact holes.

Abstract: A vertical structure non-volatile memory device in which a gate dielectric layer is prevented from protruding toward a substrate; a resistance of a ground selection line (GSL) electrode is reduced so that the non-volatile memory device is highly integrated and has improved reliability, and a method of manufacturing the same are provided. The method includes: sequentially forming a polysilicon layer and an insulating layer on a silicon substrate; forming a gate dielectric layer and a channel layer through the polysilicon layer and the insulating layer, the gate dielectric layer and the channel layer extending in a direction perpendicular to the silicon substrate; forming an opening for exposing the silicon substrate, through the insulating layer and the polysilicon layer; removing the polysilicon layer exposed through the opening, by using a halogen-containing reaction gas at a predetermined temperature; and filling a metallic layer in the space formed by removing the polysilicon layer.

Abstract: The present invention provides a method for integrating the dual metal gates and the dual gate dielectrics into a CMOS device, comprising: growing an ultra-thin interfacial oxide layer or oxynitride layer by rapid thermal oxidation; forming a high-k gate dielectric layer on the ultra-thin interfacial oxide layer by physical vapor deposition; performing a rapid thermal annealing after the deposition of the high-k; depositing a metal nitride gate by physical vapor deposition; doping the metal nitride gate by ion implantation with P-type dopants for a PMOS device, and with N-type dopants for an NMOS device, with a photoresist layer as a mask; depositing a polysilicon layer and a hard mask by a low pressure CVD process, and then performing photolithography process and etching the hard mask; removing the photoresist, and then etching the polysilicon layer/the metal gate/the high-k dielectric layer sequentially to provide a metal gate stack; forming a first spacer, and performing ion implantation with a low energy

Abstract: A method for manufacturing a semiconductor may include providing a substrate having first and second regions defined therein, forming an interlayer dielectric layer including first and second trenches formed in the first and second regions, respectively, and conformally forming a gate dielectric layer along a top surface of the interlayer dielectric layer, side and bottom surfaces of the first trench and side, and bottom surfaces of the second trench. An etch stop dielectric layer may be formed on the gate dielectric layer, a first metal layer may be formed to fill the first and second trenches, and the first metal layer in the first region may be removed using the etch stop dielectric layer as an etch stopper.

Abstract: Methods of fabricating replacement metal gate transistors using bi-layer a hardmask are disclosed. By utilizing a bi-layer hardmask comprised of a first layer of nitride, followed by a second layer of oxide, the topography issues caused by transition regions of gates are mitigated, which simplifies downstream processing steps and improves yield.

Abstract: An integrated circuit includes logic circuits of NMOS and PMOS transistors, and memory cells with NMOS and PMOS transistors. A common NSD implant mask exposes source and drain regions of a logic NMOS transistor and a memory NMOS transistor. The source and drain regions of the logic NMOS transistor and the memory NMOS transistor are concurrently implanted at a cryogenic temperature with an amorphizing species followed by arsenic. Phosphorus is concurrently implanted in the source and drain regions of the logic NMOS transistor and the memory NMOS transistor. The source and drain regions of the logic NMOS transistor are further implanted with phosphorus at a non-cryogenic temperature while the memory NMOS transistor is covered by a mask which blocks the phosphorus.

Abstract: A method of manufacturing a semiconductor device includes forming a bit line on a substrate comprising an active region; forming an interlayer insulating layer covering the bit line on the substrate; forming a first hole at a location of the active region through the interlayer insulating layer; forming a dummy contact layer by filling the first hole; forming a mold layer on the interlayer insulating layer and the dummy contact layer; forming a second hole at a location of the dummy contact layer through the mold layer; removing the dummy contact layer in the first hole through the second hole; forming an epitaxial layer on a portion of the active region, which is exposed at a lower surface of the first hole; and forming a lower electrode on internal surfaces of the first hole and the second hole.

Abstract: One embodiment of an electrostatic protection diode in an integrated circuit includes a base area having at least two bends therein.

Abstract: A method for forming an integrated circuit (IC) including a silicide block poly resistor (SIBLK poly resistor) includes forming a dielectric isolation region in a top semiconductor surface of a substrate. A polysilicon layer is formed including patterned resistor polysilicon on the dielectric isolation region and gate polysilicon on the top semiconductor surface. Implanting is performed using a first shared metal-oxide-semiconductor (MOS)/resistor polysilicon implant level for simultaneously implanting the patterned resistor polysilicon and gate polysilicon of a MOS transistor with at least a first dopant. Implanting is then performed using a second shared MOS/resistor polysilicon implant level for simultaneously implanting the patterned resistor polysilicon, gate polysilicon and source and drain regions of the MOS transistor with at least a second dopant. A metal silicide is formed on a first and second portion of a top surface of the patterned resistor polysilicon to form the SIBLK poly resistor.

Abstract: Capacitor plates, capacitors, semiconductor devices, and methods of manufacture thereof are disclosed. In one embodiment, a capacitor plate includes at least one via and at least one conductive member coupled to the at least one via. The at least one conductive member comprises an enlarged region proximate the at least one via.

Abstract: An ETSOI transistor and a capacitor are formed respectively in a transistor and capacitor region thereof by etching through an ETSOI and thin BOX layers in a replacement gate HK/MG flow. The capacitor formation is compatible with an ETSOI replacement gate CMOS flow. A low resistance capacitor electrode makes it possible to obtain a high quality capacitor or varactor. The lack of topography during dummy gate patterning are achieved by lithography in combination accompanied with appropriate etch.

Abstract: Methods and apparatus for selective one-step nitridation of semiconductor substrates is provided. Nitrogen is selectively incorporated in silicon regions of a semiconductor substrate having silicon regions and silicon oxide regions by use of a selective nitridation process. Nitrogen containing radicals may be directed toward the substrate by forming a nitrogen containing plasma and filtering or removing ions from the plasma, or a thermal nitridation process using selective precursors may be performed. A remote plasma generator may be coupled to a processing chamber, optionally including one or more ion filters, showerheads, and radical distributors, or an in situ plasma may be generated and one or more ion filters or shields disposed in the chamber between the plasma generation zone and the substrate support.

Abstract: A method for forming a nanocrystalline silicon structure for the manufacture of integrated circuit devices, e.g., memory, dynamic random access memory, flash memory, read only memory, microprocessors, digital signal processors, application specific integrated circuits. In a specific embodiment, the present invention includes providing a semiconductor substrate including a surface region. The method includes forming an insulating layer (e.g., silicon dioxide, silicon nitride, silicon oxynitride) overlying the surface region according to a specific embodiment. The method includes forming an amorphous silicon material of a determined thickness of less than twenty nanometers overlying the insulating layer. The method includes subjecting the amorphous silicon material to a thermal treatment process to cause formation of a plurality of nanocrystalline silicon structures derived from the thickness of amorphous silicon material less than twenty nanometers.

Abstract: A semiconductor device includes a first-conductivity-type semiconductor layer, a base region of a second-conductivity-type formed in an upper portion of the first-conductivity-type semiconductor layer, first though third trenches penetrating through the base region and reaching to the first-conductivity-type semiconductor layer, the first through third trenches being linked to one another, a source interconnect layer buried in the first through third trenches, the source interconnect layer including a protruding portion, a gate electrode buried in the first trench and the third trench, and formed over the source interconnect layer, a source metal contacting the protruding portion of the source interconnect layer, and a gate metal contacting the gate electrode in the third trench. A contact face between the source metal and the protruding portion at the second trench is formed higher than a contact face between the gate metal and the gate electrode at the third trench.

Abstract: In one embodiment, a vertical power transistor is formed on a semiconductor substrate with other transistors. A portion of the semiconductor layer underlying the vertical power transistor is doped to provide a low on-resistance for the vertical power transistor.

Abstract: In a method of fabricating a semiconductor device, isolation structures are formed in a substrate to define active regions. Conductive structures are formed on the substrate to cross over at least two of the active regions and the isolation structures, the conductive structures extending in a first direction. An interfacial layer is conformally formed on the substrate in contact with the conductive structures. A first insulation layer is provided on the interfacial layer, wherein the first insulation layer is formed using a flowable chemical vapor deposition (CVD) process, and wherein the interfacial layer reduces a tensile stress generated at an interface between the conductive structures and the first insulation layer while the first insulation layer is formed.

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: A semiconductor device includes: a punch stop region formed in a substrate; a plurality of buried bit lines formed over the substrate; a plurality of pillar structures formed over the buried bit lines; a plurality of word lines extending to intersect the buried bit lines and being in contact with the pillar structures; and an isolation layer isolating the word lines from the buried bit lines.

Abstract: In a method of fabricating a semiconductor device having a MISFET of trench gate structure, a trench is formed from a major surface of a semiconductor layer of first conductivity type which serves as a drain region, in a depth direction of the direction of the semiconductor layer, a gate insulating film including a thermal oxide film and a deposited film is formed over the internal surface of the trench, and after a gate electrode has been formed in the trench, impurities are introduced into the semiconductor substrate of first conductivity type to form a semiconductor region of second conductivity type which serves as a channel forming region, and impurities are introduced into the semiconductor region of second conductivity type to form the semiconductor region of first conductivity type which serves as a source region.

Abstract: The present invention belongs to the technical field of semiconductor device manufacturing and specifically relates to a method for manufacturing a tunneling field effect transistor with a U-shaped channel. The U-shaped channel can effectively extend the transistor channel length, restrain the generation of leakage current in the transistor, and decrease the chip power consumption. The method for manufacturing a tunneling field effect transistor with a U-shaped channel put forward in the present invention is capable of realizing an extremely narrow U-shaped channel, overcoming the alignment deviation introduced by photoetching, and improving the chip integration degree.

Abstract: Method for fabricating MOSFET integrated with Schottky diode (MOSFET/SKY) is disclosed. Gate trench is formed in an epitaxial layer overlaying semiconductor substrate, gate material is deposited therein. Body, source, dielectric regions are successively formed upon epitaxial layer and the gate trench. Top contact trench (TCT) is etched with vertical side walls defining Schottky diode cross-sectional width SDCW through dielectric and source region defining source-contact depth (SCD); and partially into body region by total body-contact depth (TBCD). A heavily-doped embedded body implant region (EBIR) of body-contact depth (BCD)<TBCD is created into side walls of TCT and beneath SCD. An embedded Shannon implant region (ESIR) is created into sub-contact trench zone (SCTZ) beneath TCT floor. A metal layer is formed in contact with ESIR, body and source region. The metal layer also fills TCT and covers dielectric region thus completing the MOSFET/SKY with only one-time etching of its TCT.

Abstract: Quantum-well-based semiconductor devices and methods of forming quantum-well-based semiconductor devices are described. A method includes providing a hetero-structure disposed above a substrate and including a quantum-well channel region. The method also includes forming a source and drain material region above the quantum-well channel region. The method also includes forming a trench in the source and drain material region to provide a source region separated from a drain region. The method also includes forming a gate dielectric layer in the trench, between the source and drain regions; and forming a gate electrode in the trench, above the gate dielectric layer.

Abstract: An analog transistor useful for low noise applications or for electrical circuits benefiting from tight control of threshold voltages and electrical characteristics is described. The analog transistor includes a substantially undoped channel positioned under a gate dielectric between a source and a drain with the undoped channel not being subjected to contaminating threshold voltage implants or halo implants. The channel is supported on a screen layer doped to have an average dopant density at least five times as great as the average dopant density of the substantially undoped channel which, in turn, is supported by a doped well having an average dopant density at least twice the average dopant density of the substantially undoped channel.

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: The present invention relates to a method of introducing strain into a channel and a device manufactured by using the method, the method comprising: providing a semiconductor substrate; forming a channel in the semiconductor substrate; forming a first gate dielectric layer on the channel; forming a polysilicon gate layer on the first gate dielectric layer; doping or implanting a first element into the polysilicon gate layer; removing a part of the first gate dielectric layer and polysilicon gate layer to thereby form a first gate structure; forming a source/drain extension region in the channel; forming spacers on both sides of the first gate structure; forming a source/drain in the channel; and performing annealing such that lattice change occurs in the polysilicon that is doped or implanted with the first element in the high-temperature crystallization process, thereby producing a first strain in the polysilicon gate layer, and introducing the first strain through the gate dielectric layer to the channel.

Abstract: Semiconductor devices including dual gate structures and methods of forming such semiconductor devices are disclosed. For example, semiconductor devices are disclosed that include a first gate stack that may include a first conductive gate structure formed from a first material, and a second gate stack that may include a dielectric structure formed from an oxide of the first material. For another example, methods including forming a high-K dielectric material layer over a semiconductor substrate, forming a first conductive material layer over the high-K dielectric material layer, oxidizing a portion of the first conductive material layer to convert the portion of the first conductive material layer to a dielectric material layer, and forming a second conductive material layer over both the conductive material layer and the dielectric material layer are also disclosed.

Abstract: A method for fabricating a semiconductor device includes: forming a GaN-based semiconductor layer on a substrate; forming a gate insulating film of aluminum oxide on the GaN-based semiconductor layer at a temperature equal to or lower than 450° C.; forming a protection film on an upper surface of the gate insulating film; performing a process with an alkaline solution in a state in which the upper surface of the gate insulating film is covered with the protection film; and forming a gate electrode on the gate insulating film.

Abstract: In sophisticated semiconductor devices, a semiconductor alloy, such as a threshold adjusting semiconductor material in the form of silicon/germanium, may be provided in an early manufacturing stage selectively in certain active regions, wherein a pronounced degree of recessing and material loss, in particular in isolation regions, may be avoided by providing a protective material layer selectively above the isolation regions. For example, in some illustrative embodiments, a silicon material may be selectively deposited on the isolation regions.

Abstract: A through portion is formed on a semiconductor substrate. Into the semiconductor substrate, a first ion implantation is performed via the through portion. The through portion is at least partially removed in the thickness direction from a region of at least a portion of the through portion when viewed in a plan view. A second ion implantation is performed into the semiconductor substrate at the region of at least the portion thereof. An implantation energy for the first ion implantation is equal to an implantation energy for the second ion implantation.

Abstract: According to an exemplary embodiment, a method for fabricating a MOS transistor, such as an LDMOS transistor, includes forming a self-aligned lightly doped region in a first well underlying a first sidewall of a gate. The method further includes forming a self-aligned extension region under a second sidewall of the gate, where the self-aligned extension region extends into the first well from a second well. The method further includes forming a drain region spaced apart from the second sidewall of the gate. The method further includes forming a source region in the self-aligned lightly doped region and the first well. The self-aligned lightly doped region and the self-aligned extension region define a channel length of the MOS transistor, such as an LDMOS transistor.

Abstract: A method for fabricating a semiconductor device is provided. A fin of a first conductivity type is formed on a substrate of the first conductivity type. A gate is formed on the substrate, wherein the gate covers a portion of the fin. Source and drain regions of a second conductivity type are formed in the fin at respective sides of the gate. A punch-through stopper (PTS) of the first conductivity type is formed in the fin underlying the gate and between the source and drain regions, wherein the PTS has an impurity concentration higher than that of the substrate. A first impurity of the second conductivity type is implanted into the PTS, so as to compensate the impurity concentration of the PTS.

Abstract: The present invention discloses a method of manufacturing semiconductor devices. The method includes a step of performing a chemical mechanical planarization processing on a poly-silicon layer before fabricating a poly-silicon gate such that the poly-silicon gates obtained in subsequent fabrication process are kept at the same height, which thus avoids the silicon nitride residues issue that occurs in the prior art. Therefore, the present invention is capable of enhancing product yield of semiconductor devices and improving device performances.

Abstract: There is provided fin methods for fabricating fin structures. More specifically, fin structures are formed in a substrate. The fin structures may include two fins separated by a channel, wherein the fins may be employed as fins of a field effect transistor. The fin structures are formed below the upper surface of the substrate, and may be formed without utilizing a photolithographic mask to etch the fins.

Abstract: When forming sophisticated high-k metal gate electrode structures, the removal of a dielectric cap material may be accomplished with superior process uniformity by using a silicon dioxide material. In other illustrative embodiments, an enhanced spacer regime may be applied, thereby also providing superior implantation conditions for forming drain and source extension regions and drain and source regions.

Abstract: A semiconductor device is manufactured by forming a hole as being extended through a first insulating film and an insulating interlayer stacked over a semiconductor substrate, allowing side-etching of the inner wall of the hole to proceed specifically in a portion of the insulating interlayer, to thereby form a structure having the first insulating film projected out from the edge towards the center of the hole; forming a lower electrode film as being extended over the top surface, side face and back surface of the first insulating film, and over the inner wall and bottom surface of the hole; filling a protective film in the hole; removing the lower electrode film specifically in portions fallen on the top surface and side face of the first insulating film; removing the protective film; and forming a cylindrical capacitor in the hole.

Abstract: Methods of forming a capacitor including forming at least one aperture in a support material, forming a titanium nitride material within the at least one aperture, forming a ruthenium material within the at least one aperture over the titanium nitride material, and forming a first conductive material over the ruthenium material within the at least one aperture. The support material may then be removed and the titanium nitride material may be oxidized to form a titanium dioxide material. A second conductive material may then be formed over an outer surface of the titanium dioxide material.

Abstract: Decoupling metal-insulator-metal (MIM) capacitor designs for interposers and methods of manufacture thereof are disclosed. In one embodiment, a method of forming a decoupling capacitor includes providing a packaging device, and forming a decoupling MIM capacitor in at least two metallization layers of the packaging device.

Abstract: A semiconductor structure includes a semiconductor-on-insulator substrate, the semiconductor-on-insulator substrate comprising a handle wafer, a buried oxide (BOX) layer on top of the handle wafer, and a top silicon layer on top of the BOX layer; and an implantation region located in the top silicon layer, the implantation region comprising a noble gas.

Abstract: A method of fabricating a nonvolatile memory device includes providing a substrate having active regions defined by a plurality of trenches, forming a first isolation layer on the substrate having the plurality of trenches, forming a sacrificial layer on the first isolation layer to fill the trenches, the sacrificial layer including a first region filling lower portions of the trenches and a second region filling portions other than the lower portions, removing the second region of the sacrificial layer, forming a second isolation layer on the first isolation layer and the first region of the sacrificial layer, forming air gaps in the trenches by removing the first region of the sacrificial layer, and removing a portion of the first isolation layer and a portion of the second isolation layer while maintaining the air gaps.

Abstract: Structures of a system on a chip are disclosed. In one embodiment, the system on a chip (SoC) includes an RF component disposed on a first part of a substrate, a semiconductor component disposed on a second part of the substrate, the semiconductor component and the RF component sharing a common boundary, and a conductive cage disposed enclosing the RF component. The conductive cage shields the semiconductor component from electromagnetic radiation originating from the RF circuit.

Abstract: A first bonding material layer is formed on a first substrate and a second bonding material layer is formed on a second substrate. The first and second bonding material layers include a metal. Ions are implanted into the first and second bonding material layers to induce structural damages in the in the first and second bonding material layers. The first and second substrates are bonded by forming a physical contact between the first and second bonding material layers. The structural damages in the first and second bonding material layers enhance diffusion of materials across the interface between the first and second bonding material layers to form a bonded material layer in which metal grains are present across the bonding interface, thereby providing a high adhesion strength across the first and second substrates.

Abstract: A method for manufacturing a semiconductor device makes it possible to efficiently polish with a polishing tape a peripheral portion of a silicon substrate under polishing conditions particularly suited for a deposited film and for silicon underlying the deposited film. The method includes pressing a first polishing tape against a peripheral portion of a device substrate having a deposited film on a silicon surface while rotating the device substrate at a first rotational speed, thereby removing the deposited film lying in the peripheral portion of the device substrate and exposing the underlying silicon. A second polishing tape is pressed against the exposed silicon lying in the peripheral portion of the device substrate while rotating the device substrate at a second rotational speed, thereby polishing the silicon to a predetermined depth.

Abstract: A method for testing a strip of MEMS devices, the MEMS devices including at least a respective die of semiconductor material coupled to an internal surface of a common substrate and covered by a protection material; the method envisages: detecting electrical values generated by the MEMS devices in response to at least a testing stimulus; and, before the step of detecting, at least partially separating contiguous MEMS devices in the strip. The step of separating includes defining a separation trench between the contiguous MEMS devices, the separation trench extending through the whole thickness of the protection material and through a surface portion of the substrate, starting from the internal surface of the substrate.

Abstract: The benefits of strained semiconductors are combined with silicon-on-insulator approaches to substrate and device fabrication.

Abstract: The present invention provides a non-aromatic saturated hydrocarbon group-containing organopolysiloxane containing the following units (I) to (III): (I) a siloxane unit (T unit) represented by R1SiO3/2: 40 to 99 mol %; (II) a siloxane unit (D unit) represented by R2R3SiO2/2: 59 mol % or less; and (III) a siloxane unit (M unit) represented by R4R5R6SiO1/2: 1 to 30 mol %. There can be an organopolysiloxane, which is soluble in a nonpolar organic solvent so that the organopolysiloxane can be peeled in a short time, and which is hardly soluble in a polar organic solvent to be exemplarily used upon coating a photoresist onto a semiconductor side of a joined substrate and removing the photoresist therefrom so that the organopolysiloxane is not peeled from the supporting substrate upon coating a photoresist onto a semiconductor side of a joined substrate and removing the photoresist therefrom.