Abstract: A semiconductor device includes a trench formed in a predetermined portion of a substrate and a first recess region beneath the trench. A field oxide layer is buried into both the trench and the first recess region. An active region is defined by the field oxide layer, having first active region and a second active region. The latter has a second recess region formed in lower portion of the active region than the former. A step gate pattern is formed on border region between the first active region and the second active region. The gate pattern has step structure whose one side extends to a surface of the first active region and the other side extends to a surface of the second active region. Other embodiments are also described.

Abstract: The instant disclosure relates to a high-k metal gate random access memory. The memory includes a substrate, a plurality of bit line units, source regions, gate structures, drain regions, word line units, and capacitance units. The substrate has a plurality of trenches, and the bit line units are arranged on the substrate. The source regions are disposed on the bit line units, and the gate structures are disposed on the source regions. Each gate structure has a metal gate and a channel area formed therein. The gate structures are topped with the drain regions. The word lines units are arranged between the source and drain regions. The capacitance units are disposed on the drain regions. Another memory is also disclosed, where each drain region and a portion of each gate structure are disposed in the respective capacitance unit, with the drain region being a lower electrode layer.

Abstract: An integrated circuit includes a first SONOS memory cell and a second SONOS memory cell. The second memory cell is stacked on the first memory cell.

Abstract: A spin FET includes a first ferromagnetic film disposed on a first source/drain area, a direction of magnetization thereof being fixed in an upward direction or a downward direction perpendicular to a film surface, a second ferromagnetic film disposed on a second source/drain area, a direction of magnetization thereof being changed in the upward direction or the downward direction, an anti-ferromagnetic ferroelectric film disposed on the second ferromagnetic film, and a tunnel barrier film disposed at least between the first source/drain area and the first ferromagnetic film or between the second source/drain and the second ferromagnetic film. Resistance of the anti-ferromagnetic ferroelectric film is larger than ON resistance when the first and second source/drain areas conduct electricity through the channel area.

Abstract: An electrical erasable programmable read-only memory (EEPROM) including a floating transistor formed on a semiconductor substrate and a tunneling transistor formed on a semiconductor substrate and configured to erase electrons trapped in the floating transistor. The tunneling transistor has a source junction region and a drain junction region that are integrally joined by lateral diffusion. The EPROM maintains a small cell size without any additional mask process, and is useable as an MTP EEPROM because electrical erasure is enabled. In addition, the adjustment of the width of a gate constituting the tunneling transistor ensures an improved degree of freedom to adjust an erasure voltage can be enhanced.

Abstract: According to one embodiment, a nonvolatile semiconductor memory device includes a semiconductor substrate, a first gate insulating film, a charge storage layer, a second gate insulating film, and a control gate electrode. The first gate insulating film is arranged on the semiconductor substrate. The charge storage layer is arranged on the first gate insulating film, and includes aluminum and silicon. The second gate insulating film is arranged on the charge storage layer, and includes aluminum, silicon, and lanthanum. The control gate electrode is arranged on the second gate insulating film.

Abstract: According to one embodiment, a nonvolatile semiconductor memory device includes sheet-like memory strings arranged in a matrix shape substantially perpendicularly to a substrate. A control gate electrode film includes a common connecting section that extends in a first direction and an electrode forming section that is provided for each of memory cells above or below a floating gate electrode film via an inter-electrode dielectric film to project from the common connecting section in a second direction. The floating gate electrode film extends in the second direction and is formed on a first principal plane of a sheet-like semiconductor film via a tunnel dielectric film.

Abstract: A memory device is provided, including a substrate, a conductive layer, a charge storage layer, a plurality of isolation structures, a plurality of first doped regions, and a plurality of second doped regions. The substrate has a plurality of trenches. The conductive layer is disposed on the substrate and fills the trenches. The charge storage layer is disposed between the substrate and the conductive layer. The isolation structures are disposed in the substrate between two adjacent trenches, respectively. The first doped regions are disposed in an upper portion of the substrate between each isolation structure and each trench, respectively. The second doped regions are disposed in the substrate under a bottom portion of the trenches, in which each isolation structure is disposed between two adjacent second doped regions.

Abstract: Provided is an ultra highly-integrated flash memory cell device. The cell device includes a semiconductor substrate, a first doping semiconductor area formed on the semiconductor substrate, a second doping semiconductor area formed on the first doping semiconductor area, and a tunneling insulating layer, a charge storage node, a control insulating layer, and a control electrode which are sequentially formed on the second doping semiconductor area. The first and second doping semiconductor areas are doped with impurities of the different semiconductor types According to the present invention, it is possible to greatly improve miniaturization characteristics and performance of the cell devices in conventional NOR or NAND flash memories. Unlike conventional transistor type cell devices, the cell device according to the present invention does not have a channel and a source/drain.

Abstract: According to one embodiment, a nonvolatile semiconductor memory includes first to n-th (n is a natural number not less than 2) semiconductor layers in a first direction and extend in a second direction, and the semiconductor layers having a stair case pattern in a first end of the second direction, a common semiconductor layer connected to the first to n-th semiconductor layers commonly in the first end of the second direction, first to n-th layer select transistors which are provided in order from the first electrode side between the first electrode and the first to n-th memory strings, and first to n-th impurity regions which make the i-th layer select transistor (i is one of 1 to n) a normally-on state in the first end of the second direction of the i-th semiconductor layer.

Abstract: According to one embodiment, a nonvolatile semiconductor memory includes a semiconductor layer, a first insulating layer on the semiconductor layer, a charge storage layer on the first insulating layer, a second insulating layer on the charge storage layer, and a control gate electrode on the second insulating layer. The second insulating layer comprises a stacked structure provided in order of a first lanthanum aluminate layer, a lanthanum aluminum silicate layer and a second lanthanum aluminate layer from the charge storage layer side to the control gate electrode side.

Abstract: A super-junction semiconductor substrate is configured in such a manner that an n-type semiconductor layer of a parallel pn structure is opposed to a boundary region between an active area and a peripheral breakdown-resistant structure area. A high-concentration region is formed at the center between p-type semiconductor layers that are located on both sides of the above n-type semiconductor layer. A region where a source electrode is in contact with a channel layer is formed over the n-type semiconductor layer. A portion where the high-concentration region is in contact with the channel layer functions as a diode. The breakdown voltage of the diode is set lower than that of the device.

Abstract: A semiconductor device which includes a buried layer having a first dopant type disposed in a substrate. The semiconductor device further includes a second layer having the first dopant type over the buried layer, wherein a dopant concentration of the buried layer is higher than a dopant concentration of the second layer. The semiconductor device further includes a first well of a second dopant type disposed in the second layer and a first source region of the first dopant type disposed in the first well and connected to a source contact on one side. The semiconductor device further includes a gate disposed on top of the well and the second layer and a metal electrode extending from the buried layer to a drain contact, wherein the metal electrode is insulated from the second layer and the first well by an insulation layer.

Abstract: Disclosed is a semiconductor component arrangement and a method for producing a semiconductor component arrangement. The method comprises producing a trench transistor structure with at least one trench disposed in the semiconductor body and with at least an gate electrode disposed in the at least one trench. An electrode structure is disposed in at least one further trench and comprises at least one electrode. The at least one trench of the transistor structure and the at least one further trench are produced by common process steps. Furthermore, the at least one electrode of the electrode structure and the gate electrode are produced by common process steps.

Abstract: A gate lead wiring and an electrical conductor connecting the gate lead wiring to a protective diode are arranged in a straight line without bending along one and the same side of the chip. A first gate electrode layer extending on the gate lead wiring and the electrical conductor, which connects them to the protective diode, has one bent portion or no bent portion. Further, the protective diode is arranged adjacent to the electrical conductor or the gate lead wiring, and a portion of the protective diode is arranged in close proximity to a gate pad portion.

Abstract: A semiconductor device includes a semiconductor substrate with a cell region, a second pad region, and a first pad region between the second pad region and the cell region, a first buried gate buried in a trench of the semiconductor substrate, and extended from the cell region to the second pad region, and a second buried gate buried in the trench of the semiconductor substrate, disposed over and spaced apart from an upper part of the first buried gate, and extended from the cell region to the first pad region.

Abstract: A semiconductor device includes a doped layer which contains a first dopant of a first conductivity type. In the doped layer, a counter-doped zone is formed in an edge area that surrounds an element area of the semiconductor device. The counter-doped zone contains at least the first dopant and a second dopant of a second conductivity type, which is the opposite of the first conductivity type. A concentration of the second dopant is at least 20% and at most 100% of a concentration of the first dopant. The dopants in the counter-doped zone decrease charge carrier mobility and minority carrier lifetime such that the dynamic robustness of the semiconductor device is increased.

Abstract: This invention discloses semiconductor power device that includes a plurality of top electrical terminals disposed near a top surface of a semiconductor substrate. Each and every one of the top electrical terminals comprises a terminal contact layer formed as a silicide contact layer near the top surface of the semiconductor substrate. The trench gates of the semiconductor power device are opened from the top surface of the semiconductor substrate and each and every one of the trench gates comprises the silicide layer configured as a recessed silicide contact layer disposed on top of every on of the trench gates slightly below a top surface of the semiconductor substrate surround the trench gate.

Abstract: Thin semiconductor regions and thick semiconductor regions are formed oven an insulator layer. Thick semiconductor regions include at least one semiconductor fin. A gate conductor layer is patterned to form disposable planar gate electrodes over ETSOI regions and disposable side gate electrodes on sidewalls of semiconductor fins. End portions of the semiconductor fins are vertically recessed to provide thinned fin portions adjacent to an unthinned fin center portion. After appropriate masking by dielectric layers, selective epitaxy is performed on planar source and drain regions of ETSOI field effect transistors (FETs) to form raised source and drain regions. Further, fin source and drain regions are grown on the thinned fin portions. Source and drain regions, fins, and the disposable gate electrodes are planarized. The disposable gate electrodes are replaced with metal gate electrodes. FinFETs and ETSOI FETs are provided on the same semiconductor substrate.

Abstract: A semiconductor device in which a semiconductor layer is formed on an insulating substrate with a front-end insulating layer interposed between the semiconductor layer and the insulating substrate is provided which is capable of preventing action of an impurity contained in the insulating substrate on the semiconductor layer and of improving reliability of the semiconductor device. In a TFT (Thin Film Transistor), boron is made to be contained in a region located about 100 nm or less apart from a surface of the insulating substrate so that boron concentration decreases at an average rate being about 1/1000-fold per 1 nm from the surface of the insulating substrate toward the semiconductor layer.

Abstract: A non-planar semiconductor structure includes a substrate, at least two fin-shaped structures, at least an isolation structure, and a plurality of epitaxial layers. The fin-shaped structures are located on the substrate. The isolation structure is located between the fin-shaped structures, and the isolation structure has a nitrogen-containing layer. The epitaxial layers respectively cover a part of the fin-shaped structures and are located on the nitrogen-containing layer. A non-planar semiconductor process is also provided for forming the semiconductor structure.

Abstract: The invention relates to a transistor and a method for manufacturing the transistor. The transistor according to an embodiment of the invention may comprise: a substrate which comprises at least a back gate of the transistor, an insulating layer and a semiconductor layer stacked sequentially, wherein the back gate of the transistor is used for adjusting the threshold voltage of the transistor; a gate stack formed on the semiconductor layer, wherein the gate stack comprises a gate dielectric and a gate electrode formed on the gate dielectric; a spacer formed on sidewalls of the gate stack; and a source region and a drain region located on both sides of the gate stack, respectively, wherein the height of the gate stack is lower than the height of the spacer. The transistor enables the height of the gate stack to be reduced and therefore the performance of the transistor is improved.

Abstract: An aluminum-containing material is employed to form replacement gate electrodes. A contact-level dielectric material layer is formed above a planarization dielectric layer in which the replacement gate electrodes are embedded. At least one contact via cavity is formed through the contact-level dielectric layer. Any portion of the replacement gate electrodes that is physically exposed at a bottom of the at least one contact via cavity is vertically recessed. Physically exposed portions of the aluminum-containing material within the replacement gate electrodes are oxidized to form dielectric aluminum compound portions. Subsequently, each of the at least one active via cavity is further extended to an underlying active region, which can be a source region or a drain region. A contact via structure formed within each of the at least one active via cavity can be electrically isolated from the replacement gate electrodes by the dielectric aluminum compound portions.

Abstract: A second conduction-type MIS transistor in which a source is coupled to a second power source over the surface of a first conduction-type well and a drain is coupled to the open-drain signal terminal is provided. A second conduction-type first region is provided at both sides of the MIS transistor in parallel with a direction where the electric current of the MIS transistor flows and coupled to the open-drain signal terminal. The whole these components are surrounded by a first conduction-type guard ring coupled to the second power source and the outside surrounded by the first conduction-type guard ring is further surrounded by a second conduction-type guard ring coupled to a first power source. Thereby, the semiconductor device is capable of achieving ESD protection of an open-drain signal terminal having a small area and not providing a protection element between power source terminals.

Abstract: A device includes a plurality of STI regions, a plurality of semiconductor strips between the STI regions and parallel to each other, and a plurality of semiconductor fins over the semiconductor strips. A gate stack is disposed over and crossing the plurality of semiconductor fins. A drain epitaxy semiconductor region is disposed on a side of the gate stack and connected to the plurality of semiconductor fins. The drain epitaxy semiconductor region includes a first portion adjoining the semiconductor fins, wherein the first portion forms a continuous region over and aligned to the plurality of semiconductor strips. The drain epitaxy semiconductor region further includes second portions farther away from the gate stack than the first portion. Each of the second portions is over and aligned to one of the semiconductor strips. The second portions are parallel to each other, and are separated from each other by a dielectric material.

Abstract: A structure comprises an N+ region formed over a substrate, a P+ region formed over the substrate, wherein the P+ region and the N+ region form a diode and a first epitaxial growth block region formed between the N+ region and the P+ region.

Abstract: A semiconductor device includes an n-type first doped region for receiving an external voltage, an n-type second doped region and a p-type third doped regions all formed in a p-type substrate, and is configured to have a first threshold voltage for forward conduction between the first and second doped regions, and a second threshold voltage for forward conduction between the first and third doped regions. A current is drained by flowing through the first doped region, the substrate and the second doped region if the external voltage is greater than the first threshold voltage or by flowing through the third doped region, the substrate and the first doped region if the external voltage is less than the second threshold voltage.

Abstract: An erasable programmable single-poly nonvolatile memory includes a substrate structure; a floating gate transistor having a floating gate, a gate oxide layer under the floating gate, and a channel region, wherein the channel region is formed in a N-well region; and an erase gate region, wherein the floating gate is extended to and is adjacent to the erase gate region and the erase gate region comprises a n-type source/drain region connected to an erase line voltage and a P-well region. The N-well and P-well region are formed in the substrate structure. The gate oxide layer comprises a first portion above the channel region of the floating gate transistor and a second portion above the erase gate region, and a thickness of the first portion of the gate oxide layer is different from a thickness of the second portion of the gate oxide layer.

Abstract: In one preferred form shown in FIGS. 2a to 2c there is provided a field effect transistor (24). The field effect transistor includes an off switch gate (42) and a switch bridge semiconductor (44). The switch bridge (44) is provided for charging the off switch gate (42) such that the off switch gate (42) is able to screen the electric field of the control gate (32) of the field effect transistor.

Abstract: To provide a technique capable of improving the reliability of a semiconductor device even if the downsizing thereof is advanced. The technical idea of the present invention lies in the configuration in which in a first to a third silicon nitride film to be formed by lamination, the respective film thicknesses thereof are not constant but become smaller in order from the third silicon nitride film in the upper layer to the first silicon nitride film in the lower layer while the total film thickness thereof is kept constant. Due to this it is possible to improve the embedding characteristic of the third silicon nitride film in the uppermost layer in particular, while ensuring the tensile stress of the first to third silicon nitride films, which makes effective the strained silicon technique.

Abstract: According to one embodiment, a semiconductor device includes a semiconductor substrate with a p-type conductivity, a buried layer with an n-type conductivity provided on the semiconductor substrate, a back gate layer with a p-type conductivity provided on the buried layer, a drain layer with an n-type conductivity provided on the back gate layer, a source layer with an n-type conductivity provided spaced from the drain layer, a gate electrode provided in a region immediately above a portion of the back gate layer between the drain layer and the source layer, and a drain electrode in contact with a part of an upper surface of the drain layer. A thickness of the drain layer in a region immediately below a contact surface between the drain layer and the drain electrode is half a total thickness of the back gate and drain layers in the region.

Abstract: A semiconductor device includes a first-conductivity-type first MIS transistor and a second-conductivity-type second MIS transistor. The first and second MIS transistors include a first and a second gate insulating film formed on a first and a second active region surrounded by a separation region of a semiconductor substrate, and a first and a second gate electrode formed on the first and second gate insulating films. The first and second gate insulating films are separated from each other on a first separation region of the separation region. A distance s between first ends of the first and second active regions facing each other with the first separation region being interposed therebetween, and a protrusion amount d1 from the first end of the first active region to a first end of the first gate insulating film located on the first separation region establish a relationship d1<0.5s.

Abstract: A complementary metal oxide semiconductor (CMOS) circuit incorporating a substrate and a gate wire over the substrate. The substrate comprises an n-type field effect transistor (n-FET) region, a p-type field effect transistor (p-FET) region and an isolation region disposed between the n-FET and p-FET regions. The gate wire comprises an n-FET gate, a p-FET gate, and gate material extending transversely from the n-FET gate across the isolation region to the p-FET gate. A first conformal insulator covers the gate wire and a second conformal insulator is on the first conformal insulator positioned over the p-FET gate without extending laterally over the n-FET gate. Straining regions for producing different types of strain are formed in recess etched into the n-FET and p-FET regions of the substrate.

Abstract: A method for fabricating semiconductor device is disclosed. The method includes the steps of: providing a substrate having a transistor region and a resistor region; forming a shallow trench isolation (STI) on the substrate of the resistor region; forming a tank in the STI of the resistor region; and forming a resistor in the tank and on the surface of the STI adjacent to two sides of the tank.

Abstract: A method and circuit in which the drive strength of a FinFET transistor can be selectively modified, and in particular can be selectively reduced, by omitting the LDD extension formation in the source and/or in the drain of the FinFET. One application of this approach is to enable differentiation of the drive strengths of transistors in an integrated circuit by applying the technique to some, but not all, of the transistors in the integrated circuit. In particular in a SRAM cell formed from FinFET transistors the application of the technique to the pass-gate transistors, which leads to a reduction of the drive strength of the pass-gate transistors relative to the drive strength of the pull-up and pull-down transistors, results in improved SRAM cell performance.

Abstract: A Static Random Access Memory (SRAM) cell includes a first pull-up Fin Field-Effect Transistor (FinFET) and a second pull-up FinFET, and a first pull-down FinFET and a second pull-down FinFET forming cross-latched inverters with the first pull-up FinFET and the second pull-up FinFET. A first pass-gate FinFET is connected to drains of the first pull-up FinFET and the first pull-down FinFET. A second pass-gate FinFET is connected to drains of the second pull-up FinFET and the second pull-down FinFET, wherein the first and the second pass-gate FinFETs are p-type FinFETs. A p-well region is in a center region of the SRAM cell and underlying the first and the second pull-down FinFETs. A first and a second n-well region are on opposite sides of the p-well region.

Abstract: A semiconductor device is formed with low resistivity self aligned silicide contacts with high-K/metal gates. Embodiments include postponing silicidation of a metal layer on source/drain regions in a silicon substrate until deposition of a high-K dielectric, thereby preserving the physical and morphological properties of the silicide film and improving device performance. An embodiment includes forming a replaceable gate electrode on a silicon-containing substrate, forming source/drain regions, forming a metal layer on the source/drain regions, forming an ILD over the metal layer on the substrate, removing the replaceable gate electrode, thereby forming a cavity, depositing a high-K dielectric layer in the cavity at a temperature sufficient to initiate a silicidation reaction between the metal layer and underlying silicon, and forming a metal gate electrode on the high-K dielectric layer.

Abstract: The invention relates to integrated circuit fabrication, and more particularly to a Field Effect Transistor with a low resistance metal gate electrode. An exemplary structure for a gate electrode for a Field Effect Transistor comprises a lower portion formed of a first metal material having a recess and a first resistance; and an upper portion formed of a second metal material having a protrusion and a second resistance, wherein the protrusion extends into the recess, wherein the second resistance is lower than the first resistance.

Abstract: A microelectromechanical system (MEMS) assembly includes at least one emission source; a top wafer having a plurality of side walls and a generally horizontal portion, the horizontal portion having a thickness between a first side and a directly opposed second side, at least one window in the horizontal portion extending between the first and second sides and a transmission membrane across the at least one window; and a bottom wafer having a first portion with a first substantially planar surface, an intermediate surface directly opposed to the first substantially planar surface, a second portion with a second substantially planar surface, the at least one emission source provided on the second substantially planar surface; where the top wafer bonds to the bottom wafer at the intermediate surface and encloses a cavity within the top wafer and the bottom wafer.

Abstract: Backside recesses in a base member host components, such as sensors or circuits, to allow closer proximity and efficient use of the surface space and internal volume of the base member. Recesses may include covers, caps, filters and lenses, and may be in communication with circuits on the frontside of the base member, or with circuits on an active backside cap. An array of recessed components may a form complete, compact sensor system.

Abstract: In one embodiment, a method of opening a passageway to a cavity includes providing a donor portion, forming a heating element adjacent to the donor portion, forming a first sacrificial slab abutting the donor portion, wherein the donor portion and the sacrificial slab are a shrinkable pair, forming a first cavity, a portion of the first cavity bounded by the first sacrificial slab, generating heat with the heating element, forming a first reduced volume slab from the first sacrificial slab using the generated heat and the donor portion, and forming a passageway to the first cavity by forming the first reduced volume slab.

Abstract: A motion-sensitive low-G MEMS acceleration switch, which is a MEMS switch that closes at low-g acceleration (e.g., sensitive to no more than 10 Gs), is proposed. Specifically, the low-G MEMS acceleration switch has a base, a sensor wafer with one or more proofmasses, an open circuit that includes two fixed electrodes, and a contact plate. During acceleration, one or more of the proofmasses move towards the base and connects the two fixed electrodes together, resulting in a closing of the circuit that detects the acceleration. Sensitivity to low-G acceleration is achieved by proper dimensioning of the proofmasses and one or more springs used to support the proofmasses in the switch.

Abstract: Integrated devices and methods for packaging the same can include an external housing, an internal housing positioned within the external housing, and an external cavity formed between the external housing and the internal housing. An integrated device die can be positioned within the external cavity in fluid communication with an internal cavity formed by the internal lid. An air way can extend through the external cavity to the internal cavity, and can further extend from the internal cavity to the external cavity. The air way can provide fluid communication between the package exterior and the integrated device die, while reducing contamination of the integrated device die.

Abstract: A pressure sensor component includes a MEMS component having at least one pattern element that is able to be deflected perpendicular to the component plane, which is equipped with at least one electrode of a measuring capacitor device, and an ASIC component having integrated circuit elements and at least one back end stack, at least one counter-electrode of the measuring capacitor device being developed in a metallization plane of the back end stack. The MEMS component is mounted on the back end pile of the ASIC component. The MEMS component includes at least one pressure-sensitive diaphragm pattern and is mounted on the ASIC component in such a way that the pressure-sensitive diaphragm pattern spans a cavity between the MEMS component and the back end stack of the ASIC component.

Abstract: A spin transfer torque memory random access memory (STTMRAM) element is capable of switching states when electrical current is applied thereto for storing data and includes the following layers. An anti-ferromagnetic layer, a fixed layer formed on top of the anti-ferromagnetic layer, a barrier layer formed on top of the second magnetic layer of the fixed layer, and a free layer including a first magnetic layer formed on top of the barrier layer, a second magnetic layer formed on top of the first magnetic layer, a nonmagnetic insulating layer formed on top of the second magnetic layer and a third magnetic layer formed on top of the non-magnetic insulating layer. A capping layer is formed on top of the non-magnetic insulating layer.

Abstract: In one embodiment, a magnetic element for a semiconductor device includes a reference layer, a free layer, and a nonmagnetic spacer layer disposed between the reference layer and the free layer. The nonmagnetic spacer layer includes a binary, ternary, or multi-nary alloy oxide material. The binary, ternary, or multi-nary alloy oxide material includes MgO having one or more additional elements selected from the group consisting of: Ru, Al, Ta, Tb, Cu, V, Hf, Zr, W, Ag, Au, Fe, Co, Ni, Nb, Cr, Mo, and Rh.

Abstract: An image sensor comprises a substrate, a plurality of photoelectric transducer devices, an interconnect structure, at least one dielectric isolator and a back-side alignment mark. The substrate has a front-side surface and a back-side surface opposite to the front-side surface. The interconnect structure is disposed on the front-side surface. The photoelectric transducer devices are formed on the front-side surface. The dielectric isolator extends downwards into the substrate from the back-side surface in order to isolate the photoelectric transducer devices. The back-side alignment mark extends downwards into the substrate from the back-side surface and references to a front-side alignment mark previously formed on the front-side surface.

Abstract: Light sensor devices are described that have a glass substrate, which includes a lens to focus light over a wide variety of angles, bonded to the light sensor device. In one or more implementations, the light sensor devices include a substrate having a photodetector formed therein. The photodetector is capable of detecting light and providing a signal in response thereto. The sensors also include one or more color filters disposed over the photodetector. The color filters are configured to pass light in a limited spectrum of wavelengths to the photodetector. A glass substrate is disposed over the substrate and includes a lens that is configured to collimate light incident on the lens and to pass the collimated light to the color filter.

Abstract: A solid-state imaging device including a plurality of pixels arranged two-dimensionally, wherein each of the pixels has at least a planarizing film formed on the upper side of a photoelectric conversion element, a filter formed on the upper side of the planarizing film, and a microlens formed on the upper side of the filter. The filter of some of the pixels is a color filter permitting transmission therethrough of light of a predetermined color component, whereas the filter of other pixels is a white filter permitting transmission therethrough of light in the whole visible spectral range. The refractive indices of the white filter, the microlens and the planarizing film have the following relationship: (Refractive index of white filter)?(Refractive index of microlens)>(Refractive index of planarizing film).

Abstract: Photodetectors, methods for use in manufacturing photodetectors, and systems including photodetectors, are described herein. In an embodiment, a photodetector includes a plurality of photodiode regions, at least some of which are covered by an optical filter. A plurality of metal layers are located between the photodiode regions and the optical filter. The metal layers include an uppermost metal layer that is closest to the optical filter and a lowermost metal layer that is closest to the photodiode regions. One or more inter-level dielectric layers separate the metal layers from one another. Each of the metal layers includes one or more metal portions and one or more dielectric portions. The uppermost metal layer is devoid of any metal portions underlying the optical filter.