Abstract: A semiconductor device includes a die pad including a first surface and a second surface opposite to the first surface, a first chip arranged in a first area on the first surface, the first chip including a first side and a second side crossing to the first side, a second chip arranged in a second area on the first surface, the second chip including a third side and a fourth side crossing to the third side, a plurality of first marks formed on the first surface, the first marks including a third mark and a fourth mark, a plurality of second marks formed on the first surface, the second marks including a fifth mark and sixth mark. The semiconductor device also includes a wire and a resin encapsulating the first chip, the second chip, and the wire.

Abstract: A solid-state imaging device includes a semiconductor substrate configured to include a solid-state imaging element that is provided with a photoelectric conversion region, and a scribe line region that is provided along a periphery of the solid-state imaging element, a wiring layer that is formed to be layered on the semiconductor substrate, a support substrate that is formed to be layered on the wiring layer, and a groove that is provided between a blade region in the scribe line region and the solid-state imaging element, in the semiconductor substrate and penetrates through the semiconductor substrate.

Abstract: A semiconductor circuit design includes an outer seal-ring and an inner seal-ring for each sub-section of the design that may potentially be cut into separate die. The use of multiple seal-rings permits a single circuit design and fabrication run to be used to support flexibly packaging different product releases having different numbers of integrated circuit blocks per packaged unit.

Abstract: A method of forming a semiconductor light emitting element. The method can include forming a seed layer on a semiconductor layer assembly including at least one nitride semiconductor layer. An insulating mask can be formed on the seed layer. The insulating mask can include a plurality of element areas separated by cross spaces. Each element area of the plurality of element areas can be connected to at least one of the other element areas of the plurality of element areas. The seed layer can be plated such that a plating substrate is formed in each of the plurality of element areas.

Abstract: A method for producing semiconductor device includes: performing first, second and third exposures of a photoresist film formed on a semiconductor wafer via a mask; wherein: first, second and third shot regions respectively defined by the first, second and third exposures are aligned in a first direction; the mask has a shot region including a peripheral scribe region having a first and second side crossing the first direction; the photoresist film is of positive type, a first pattern is formed as a light shielding pattern disposed on the first side, and a second pattern is formed as a light transmitting region disposed on the second side; the first and second exposures are performed in such a manner that the first and second patterns do not overlap each other; and the second and third exposures are performed in such a manner that the first and second patterns overlap each other.

Abstract: A WLCSP method comprises: depositing a metal bump on bonding pads of chips; forming a first packaging layer at front surface of wafer to cover metal bumps while forming an un-covered ring at the edge of wafer to expose the ends of each scribe line located between two adjacent chips; thinning first packaging layer to expose metal bumps; forming a groove on front surface of first packaging layer along each scribe line by cutting along a straight line extended by two ends of scribe line exposed on front surface of un-covered ring; grinding back surface of wafer to form a recessed space and a support ring at the edge of the wafer; depositing a metal layer at bottom surface of wafer in recessed space; cutting off the edge portion of wafer; and separating individual chips from wafer by cutting through first packaging layer, the wafer and metal layer along groove.

Abstract: The invention relates to a serial connection of thin layer solar cells. The invention provides a structuring method for creating a reliable and effective connections, preventing short-circuits and enlarging usable solar cell surfaces. The solar cells comprise a substrate, a back contact layer, an absorber layer, a buffer layer, and a transparent front contact layer. Each solar cell is subdivided by three trenches A, B, C to create a plurality of adjacent cell segments. Trenches A and B extend down to the back contact layer, trench C extends down to the substrate. Trench C is filled with electrically insulating paste and trench B is filled with electrically conducting paste. The electrically conducting paste also covers trench C. The adjacent cell segments are electrically connected. Trench A is then created and filled with electrically insulating paste.

Abstract: The present invention provides a method for plasma dicing a substrate. The method comprising providing a process chamber having a wall; providing a plasma source adjacent to the wall of the process chamber; providing a work piece support within the process chamber; placing the substrate onto a support film on a frame to form a work piece work piece; loading the work piece onto the work piece support; providing a cover ring disposed above the work piece; generating a plasma through the plasma source; and etching the work piece through the generated plasma.

Abstract: The various aspects comprise methods and devices for processing a wafer. An aspect of this disclosure includes a wafer. The wafer comprises a plurality of die regions; a plurality of kerf regions between the plurality of die regions; and a metallization area on the plurality of die regions.

Abstract: To divide a semiconductor wafer by stealth dicing, a test pad in a cutting region and an alignment target are collectively arranged along one side in a width direction of the cutting region, and a laser beam for forming a modified region is irradiated to a position away in plane from the test pad and the alignment target Am. In this manner, defects in cutting shape in a cutting process of a semiconductor wafer using stealth dicing can be reduced or prevented.

Abstract: A semiconductor wafer with an assisting dicing structure. The wafer comprises a substrate having a front surface and a rear surface. The front surface of the substrate comprises at least two device regions separated by at least one dicing lane. The rear surface of the substrate comprises at least one pre-dicing trench formed therein and substantially aligned with the dicing lane. A method for dicing a semiconductor wafer is also disclosed.

Abstract: A method for fabricating a semiconductor device, wherein the method comprises steps as follows: Firstly, a device wafer is provided and a patterned bonding layer is then formed within a scribe line region of the device wafer. Subsequently a handle wafer is bonded to the device wafer by the patterned bonding layer. Next, a dicing process is performed along the scribe line region in order to divide the device wafer into a plurality of dices and remove the patterned bonding layer simultaneously, whereby the divided dices can be separated from the handle wafer.

Abstract: A backside illuminated image sensor includes a light receiving element disposed in a first substrate, an interlayer insulation layer disposed on the first substrate having the light receiving element, an align key spaced apart from the light receiving element and passing through the interlayer insulation layer and the first substrate, a plurality of interconnection layers disposed on the interlayer insulation layer in a multi-layered structure, wherein the backside of the lowermost interconnection layer is connected to the align key, a passivation layer covering the interconnection layers, a pad locally disposed on the backside of the first substrate and connected to the backside of the align key, a light anti-scattering layer disposed on the backside of the substrate having the pad, and a color filter and a microlens disposed on the light anti-scattering layer to face the light receiving element.

Abstract: Methods of dicing substrates by both laser scribing and plasma etching. A method includes laser ablating material layers, the ablating leading with a first irradiance and following with a second irradiance, different than the first. An asymmetrically shaped beam having an asymmetrical spatial profile along the direction of travel, multiple passes of a beam adjusted to have different irradiance levels, and multiple laser beams having various irradiance levels may be utilized to ablate at least a mask with the first irradiance and expose the substrate with the second irradiance.

Abstract: A wafer is disclosed. The wafer comprises a plurality of chips and a plurality of kerfs. A kerf of the plurality of kerfs separates one chip from another chip. The kerf comprises a crack stop barrier.

Abstract: A semiconductor wafer including an electrostatic discharge (ESD) protective device, and methods for fabricating the same. In one aspect, the method includes forming a first semiconductor device in a first semiconductor die region on the semiconductor wafer; forming a second semiconductor device in a second semiconductor die region on the semiconductor wafer; and forming a protective device in a scribe line region between (i) the first semiconductor die region and (ii) the second semiconductor die region.

Abstract: A method for preparing a semiconductor wafer into individual semiconductor dies uses both a dicing before grinding step and/or via hole micro-fabrication step, and an adhesive coating step.

Abstract: A semiconductor construct includes a semiconductor substrate and connection pads provided on the semiconductor substrate. Some of the connection pads are connected to a common wiring and at least one of the remaining of the connection pads are connected to a wiring. The construct also includes a first columnar electrode provided to be connected to the common wiring and a second columnar electrode provided to be connected to a connection pad portion of the wiring.

Abstract: A wafer processing method of dividing a wafer along streets. The wafer processing method includes a protective tape attaching step of attaching a protective tape to the front side of the wafer, a modified layer forming step of holding the wafer through the protective tape on a chuck table of a laser processing apparatus under suction and next applying a laser beam having a transmission wavelength to the wafer from the back side of the wafer along the streets, thereby forming a modified layer inside the wafer along each street, and a wafer dividing step of canceling suction holding of the wafer by the chuck table and next applying an air pressure to the wafer now placed on the holding surface in the condition where horizontal movement of the wafer is limited, thereby dividing the wafer along each street where the modified layer is formed, thus obtaining individual devices.

Abstract: A thinning method of a wafer is provided. The method includes the following steps. First, a wafer having a first surface, a second surface, and a side surface is provided, and the side surface is connected between the first surface and the second surface. At least one semiconductor device is formed on the first surface. Then, an anisotropy etching process is performed to the second surface with a mask to remove portions of the wafer while remaining the side surface thereby forming a number of grooves in the second surface and at least one reinforcing wall between the grooves. As a result, a thinned wafer is obtained.

Abstract: A semiconductor chip includes a first mark for identifying a position of the chip within an exposure field. The semiconductor chip includes a first matrix in a first layer of the chip and a second mark within the first matrix identifying a position of the exposure field on a wafer.

Abstract: Test structures for semiconductor devices, methods of forming test structures, semiconductor devices, methods of manufacturing thereof, and testing methods for semiconductor devices are disclosed. In one embodiment, a test structure for a semiconductor device includes at least one first contact pad disposed in a first material layer in a scribe line region of the semiconductor device. The at least one first contact pad has a first width. The test structure also includes at least one second contact pad disposed in a second material layer proximate the at least one first contact pad in the first material layer. The at least one second contact pad has a second width that is greater than the first width.

Abstract: A method to minimize edge-related substrate breakage during spalling using an edge-exclusion region where the stressor layer is either non-present (excluded either during deposition or removed afterwards) or present but significantly non-adhered to the substrate surface in the exclusion region is provided. In one embodiment, the method includes forming an edge exclusion material on an upper surface and near an edge of a base substrate. A stressor layer is then formed on exposed portions of the upper surface of the base substrate and atop the edge exclusion material, A portion of the base substrate that is located beneath the stressor layer and which is not covered by the edge exclusion material is then spalled.

Abstract: An embodiment 3DIC device includes a semiconductor chip, a die, and a polymer. The semiconductor chip includes a semiconductor substrate, wherein the semiconductor substrate comprises a first edge, and a low-k dielectric layer over the semiconductor substrate. The die is disposed over and bonded to the semiconductor chip. The polymer is molded onto the semiconductor chip and the die. The polymer includes a portion level with the low-k dielectric layer, wherein the portion of the polymer comprises a second edge vertically aligned to the first edge of the semiconductor substrate and a third edge contacting the low-k dielectric layer, wherein the second and the third edges are opposite edges of the portion of the polymer.

Abstract: A method of manufacturing semiconductor wafers is provided which facilitates formation of orientation flat lines and allows beveling work without problems. The method of manufacturing semiconductor wafers according to the present invention is a method of manufacturing semiconductor wafers, in which a plurality of small-diameter wafers is cut out from a large-diameter semiconductor wafer, the method including: a marking step of forming straight groove-like orientation flat lines by a laser beam so as to cross the respective small-diameter wafers in each row in the large-diameter semiconductor wafer, wherein cutout positions of the small-diameter wafers are aligned in rows in a specific direction, collectively for each of the rows; and a cutting step of cutting out the small-diameter wafers separately from the large-diameter semiconductor wafer by a laser beam after the marking step.

Abstract: Disclosed herein are techniques of manufacturing semiconductor devices having a positive-bevel termination and/or a negative-bevel termination. In a particular example, techniques are disclosed for manufacture of a chip-size SiC device having an orthogonal positive-bevel termination used for the reverse blocking junction. The edge termination may be formed, for example, by cutting across a SiC wafer with a V-shaped dicing tool or blade. The cut may be performed by any suitable dicing tool. The cut may be across a p-n junction for forming positive-bevel termination. Subsequently, a surface of the termination may be etched for removing damage caused by the cutting process.

Abstract: A semiconductor wafer includes: a first semiconductor chip area formed with a semiconductor element; a second semiconductor chip area formed with a semiconductor element; and a scribe area sandwiched between the first and second semiconductor chip areas; wherein: the first semiconductor chip area includes a first metal ring surrounding the semiconductor element formed in the first semiconductor chip area; and the metal ring is constituted of a plurality of metal layers including a lower metal layer and an upper metal layer superposed upon the lower metal layer, and the upper metal layer is superposed upon the lower metal layer in such a manner that an outer side wall of the upper metal layer is flush with the outer side wall of the lower metal layer or is at an inner position of the first semiconductor chip area relative to the outer side wall of the lower metal layer.

Abstract: A thin overlay structure for use in imaging based metrology is disclosed. The thin overlay structure may include a first structure and second structure, the first and second structures designed to have a common center of symmetry, both structures being invariant to a 180 degree rotation about the common center of symmetry, wherein a mark region defining the extent of the structures is characterized by a first direction and a second direction orthogonal to the first direction, a length of the mark region along the first direction being greater than a length of the mark region along the second direction.

Abstract: The disclosure relates to a method of fabricating an integrated circuit of CMOS technology in a semiconductor wafer comprising scribe lines. According to the disclosure, a ground contact pad of the integrated circuit is made in a scribe line of the wafer and is destroyed during a step of individualizing the integrated circuit by singulation of the wafer. A ground contact of the integrated circuit is made on the back side of the integrated circuit when it is assembled in an interconnection package.

Abstract: In various embodiments, an assembly having a microstructure is provided, the device includes a cylindrical capture receptacle associated with a substrate, the capture receptacle comprising of a material having an expansion coefficient and comprising alignment structures having alignment projections extending inward from a periphery of the cylindrical capture receptacle. In one embodiment, the projections include a large width alignment projection and plurality of small width alignment projections. A plurality of medium width alignment projections also may be provided. A cylindrical key is associated with the microstructure and has a smaller circumference than the cylindrical capture receptacle and is comprised of a material having an expansion coefficient greater than the expansion coefficient of the cylindrical capture receptacle. The cylindrical key includes alignment receptacles spaced about a periphery of the cylindrical base to receive corresponding alignment projections.

Abstract: A method of making an edge-reinforced microelectronic element is disclosed. The steps include mechanically cutting along dicing lanes of a substrate at least partially through a thickness thereof to form a plurality of edge surfaces extending away from a front surface thereof and forming a continuous monolithic metallic edge-reinforcement ring that covers each of the plurality of edge surfaces and extends onto the front surface. The front surface may have a plurality of contacts thereat and the substrate may embody a plurality of microelectronic elements.

Abstract: A wafer processing method divides a wafer into individual devices along crossing streets formed on the front side of the wafer. The wafer has a substrate and a functional layer formed on the front side of the substrate. The individual devices are formed from the functional layer and are partitioned by the streets. A laser beam is applied along the streets from the front side of the functional layer to thereby remove the functional layer along the streets. A resist film is formed on the front side of the functional layer except on each street. The substrate of the wafer is plasma-etched along each street where the functional layer is absent to the depth corresponding to the finished thickness of each device, thereby forming a division groove along each street and also etching off a modified layer formed on the opposite sides of each street.

Abstract: A method for manufacturing a semiconductor element of the present invention, has: a laser irradiation step of focusing a pulsed laser beam inside of a substrate constituting a wafer, thereby forming a plurality of isolated processed portions along an intended dividing line inside of the substrate, and creating a fissure that runs from the processed portions at least to the surface of the substrate and links adjacent processed portions; and a wafer division step of dividing the wafer along the intended dividing line.

Abstract: A wafer laser-marking method is provided. First, a wafer having a first surface (an active surface) and a second surface (a back surface) opposite to each other is provided. Next, the wafer is thinned. Then, the thinned wafer is fixed on a non-UV tape such that the second surface of the wafer is attached to the tape. Finally, the laser marking step is performed, such that a laser light penetrates the non-UV tape and marks a pattern on the second surface of the wafer. According to the laser-marking method of the embodiment, the pattern is formed by the non-UV residuals left on the second surface of the wafer, and the components of the glue residuals at least include elements of silicon and carbon.

Abstract: Fractures (17a, 17b) are generated from modified regions (7a, 7b) to front and rear faces (12a, 12b) of a object to be processed (1), respectively, while an unmodified region (2) is interposed between the modified regions (7a, 7b). This can prevent fractures from continuously advancing in the thickness direction of a silicon substrate (12) when forming a plurality of rows of modified regions (7). By generating a stress in the object (1), the fractures (17a, 17b) are connected to each other in the unmodified region (2), so as to cut the object (1). This can prevent fractures from meandering in the rear face (12b) of the object (1) and so forth, whereby the object (1) can be cut accurately along a line to cut the object (5).

Abstract: Various semiconductor workpieces and methods of dicing the same are disclosed. In one aspect, a method of manufacturing is provided that includes forming a channel in a metallization structure on a backside of a semiconductor workpiece. The semiconductor workpiece includes a substrate. The channel is in substantial alignment with a dicing street on a front side of the semiconductor chip.

Abstract: The invention relates to production of alignment marks on a semiconductor wafer with the use of a light-opaque layer (17), wherein, before the light-opaque layer (17) is applied, by means of the etching of cavities, free-standing pillar groups are produced in the cavities and then the light-opaque layer (17) is applied. The pillars are produced with a height of above 1 ?m, which, moreover, is greater than a thickness of the light-opaque layer (17) to be applied in the cavities as layer portions (17x; 17y). The cavities are formed with a width such that they are filled only partly with the layer portions (17x; 17y) when the light-opaque layer (17) is applied. The high, freely positioned alignment marks produced by the method as pillar series (16x; 16y), having a plurality of individual pillars (16a; 16a?) in a cavity (12a, 12y), of a scribing trench on the semiconductor wafer are likewise described.

Abstract: In a wafer processing method, grooves are formed on the front side of a wafer along all division lines extending in a first direction and along all division lines extending in a second direction perpendicular to the first direction. Each groove has a depth corresponding to a finished thickness of each device in the wafer. The wafer is cut into four sectorial wafer quarters. A protective member is provided on the front side of each wafer quarter; and the back side of the wafer quarter is ground to reduce the thickness of the wafer quarter to the finished thickness until the grooves are exposed to the back side of the wafer quarter, thereby dividing the wafer quarter into the individual devices.

Abstract: A wafer processing method includes: a protective member providing step of providing a protective member on the front side of a wafer; a wafer quarter generating step of cutting the wafer along the division line extending in a first direction through the center of the wafer and along the division line extending in a second direction perpendicular to the first direction through the center of the wafer, thereby generating four sectorial wafer quarters; a back grinding step of grinding the back side of each wafer quarter to reduce the thickness of the wafer quarter; a frame providing step of supporting the wafer quarter through an adhesive tape to an annular frame; and a wafer quarter dividing step of fully cutting the wafer quarter along all of the division lines extending in the first and second directions, thereby dividing the wafer quarter into the individual devices.

Abstract: In a wafer processing method, a wafer is cut along a division line extending in a first direction through the center of the wafer and along a division line extending in a second direction through the center of the wafer, thereby generating four sectorial wafer quarters. Grooves are formed on the front side of each wafer quarter along other division lines extending in a grid, each groove having a depth corresponding to a finished thickness of each device formed on the wafer quarter. A protective member is provided on the front side of each wafer quarter; and the wafer quarter is held through the protective member on a chuck table. The back side is then ground to reduce the thickness of the wafer quarter until the grooves are exposed to the back side of the wafer quarter, thereby dividing the wafer quarter into the individual devices.

Abstract: A chip package and a fabrication method thereof are provided according to an embodiment of the invention. The chip package contains a semiconductor substrate having a chip. A packaging layer is disposed over the semiconductor substrate. A spacer is disposed between the semiconductor substrate and the packaging layer, wherein a side surface consisting of the semiconductor substrate, the spacer and the packaging layer has a recess section. The method includes forming a plurality of spacers between a plurality of chips of a semiconductor wafer and a packaging layer, wherein each spacer corresponding to each chip is separated from each other and the spacer is shrunk inward from an edge of the chip to form a recess section and dicing the semiconductor wafer along a scribe line between any two adjacent chips to form a plurality of chip packages.

Abstract: The invention provides a transferring apparatus for a flexible electronic device and method for fabricating a flexible electronic device. The transferring apparatus for the flexible electronic device includes a carrier substrate. A release layer is disposed on the carrier substrate. An adhesion layer is disposed on a portion of the carrier substrate, surrounding the release layer and adjacent to a sidewall of the release layer. A flexible electronic device is disposed on the release layer and the adhesion layer, wherein the flexible electronic device includes a flexible substrate.

Abstract: The present disclosure relates to the field of microelectronic die packaging, particularly multi-chip packaging, wherein on-substrate modularity is enabled by using in-street die-to-die interconnects to facilitate signal routing between microelectronic dice. These in-street die-to-die interconnects may allow for manufacturing of several products on a single microelectronic substrate, which may lead to improved microelectronic die and/or microelectronic module harvesting and increased product yields.

Abstract: Methods of dicing semiconductor wafers, each wafer having a plurality of integrated circuits, are described. A method includes forming a mask above the semiconductor wafer. The mask is composed of a layer covering and protecting the integrated circuits. The mask is patterned with a multi-step laser scribing process to provide a patterned mask with gaps. The patterning exposes regions of the semiconductor wafer between the integrated circuits. The semiconductor wafer is then etched through the gaps in the patterned mask to singulate the integrated circuits.

Abstract: Methods of dicing semiconductor wafers, each wafer having a plurality of integrated circuits, are described. A method includes forming a mask above the semiconductor wafer, the mask including a layer covering and protecting the integrated circuits. The mask and a portion of the semiconductor wafer are patterned with a laser scribing process to provide a patterned mask and to form trenches partially into but not through the semiconductor wafer between the integrated circuits. Each of the trenches has a width. The semiconductor wafer is plasma etched through the trenches to form corresponding trench extensions and to singulate the integrated circuits. Each of the corresponding trench extensions has the width.

Abstract: Systems and methods are disclosed for modulating the hydrostatic pressure in a double side wafer grinder having a pair of grinding wheels. The systems and methods use a processor to measure the amount of electrical current drawn by the grinding wheels. Pattern detection software is used to predict a grinding stage based on the measured electrical current. The hydrostatic pressure is changed by flow control valves at each stage to change the clamping pressure applied to the wafer and to thereby improve nanotopology in the processed wafer.

Abstract: A method of manufacturing a plurality of electronic devices is provided. Each one of a plurality of first conductive terminals on a plurality of integrated circuits formed on a device wafer is connected to a respective one of a plurality of second conductive terminals on a carrier wafer, thereby forming a combination wafer assembly. The combination wafer assembly is singulated between the integrated circuits to form separate electronic assemblies. The combination wafer assembly also allows for an underfill material to be introduced and to cured at wafer level and for thinning of the device wafer at wafer level without requiring a separate supporting substrate. Alignment between the device wafer and the carrier wafer can be tested by conducting a current through first and second conductors in the device and carrier wafers, respectively.

Abstract: A method for manufacturing a substrate for a display device comprises forming a first pattern within an active region of the substrate and at the same time forming a first overlay pattern at corner regions of the active region; and forming a second pattern within the active region of the substrate and at the same time forming a second overlay pattern at corner regions of the active region, wherein the first overlay pattern includes gradations arranged in a predetermined direction, and the second overlay pattern includes gradations arranged in the predetermined direction to face the gradations of the first overlay pattern.

Abstract: A method of preparing semiconductor dies from a semiconductor wafer having a plurality of fabrication regions separated by dicing lines on the top side of the wafer, and an adhesive coating on the back side of the wafer, comprises applying a repellent material to the fabrication regions and dicing lines where the adhesive coating is not intended to be printed; applying the adhesive coating to the back side of the wafer; removing the repellent material; and separating the wafer along the dicing lines into individual dies.

Abstract: The present invention discloses a method for cutting a substrate. The method includes the steps of 1) creating a etching groove in the first surface of the first sheet and the third surface of the second sheet; 2) laminating the first and second sheets with the etching grooves aligned with each other; and 3) using a cutter to cut through the second surface of first sheet and the fourth surface of the second sheet along a preset set cutting line such that a crack extending vertically to the etching grooves so as to sever the first and second sheets. The present invention further discloses a substrate. By way of the foregoing, the taper and gradient along the cutting edge can be reduced.