Patent application number | Description | Published |
20090108472 | WAFER-LEVEL UNDERFILL PROCESS USING OVER-BUMP-APPLIED RESIN - A process of fabricating wafer-level underfilled microelectronic packages using over-bump application of a self-fluxing resin to a wafer, b-staging of the resin, dicing of the coated wafer, and joining the diced chips to substrates producing wafer-level underfilled microelectronic flip-chip packages. Moreover, provided are microelectronic packages, which are produced in accordance with the inventive process. | 04-30-2009 |
20090236699 | DISCREET PLACEMENT OF RADIATION SOURCES ON INTEGRATED CIRCUIT DEVICES - An integrated circuit and methods of forming and using the integrated circuit. The circuit includes: a radiation-emitting layer over a selected region of a top surface of an integrated circuit chip, the radiation emitting layer comprising a first polymer or resin and a first radioactive material, the region smaller than a whole of the top surface of the integrated circuit chip, the region including a circuit that is liable to temporary failure when struck by radiation generated by the first radioactive material. | 09-24-2009 |
20090251698 | METHOD AND SYSTEM FOR COLLECTING ALIGNMENT DATA FROM COATED CHIPS OR WAFERS - A process and system for determining alignment data for features on wafers or chips when a wafer or chip is substantially coated by an over bump applied material, e.g. a resin or film, and using that data to align the wafers or chips for subsequent operations such as dicing or joining. Position data for alignment is produced by identifying a location of an at least partially obscured feature by varying the depth of focus upon a work piece to determine an SNR approximating a maximum value from an image captured by optical scanning. An SNR above a threshold value can be employed. | 10-08-2009 |
20090263991 | Negative Thermal Expansion System (NTES) Device for TCE Compensation in Elastomer Compsites and Conductive Elastomer Interconnects in Microelectronic Packaging - A method for fabricating a negative thermal expanding system device includes coating a wafer with a thermally decomposable polymer, patterning the decomposable polymer into repeating disk patterns, releasing the decomposable polymer from the wafer and forming a sheet of repeating patterned disks, suspending the sheet into a first solution with seeding compounds for electroless decomposition, removing the sheet from the first solution, suspending the sheet into a second solution to electrolessly deposit a first layer material onto the sheet, removing the sheet from the second solution, suspending the sheet into a third solution to deposit a second layer of material having a lower TCE value than the first layer of material, separating the patterned disks from one another, and annealing thermally the patterned disks to decompose the decomposable polymer and creating a cavity in place of the decomposable polymer. | 10-22-2009 |
20100003786 | CHIP-LEVEL UNDERFILL PROCESS AND STRUCTURES THEREOF - A process comprises forming a first electrical interconnect structure on a surface of a singulated semiconductor chip having an alignment pattern. The alignment pattern is scanned and stored in a scanning device prior to application of a curable underfill coating to the surface of the singulated semiconductor chip. This is followed by applying a curable underfill coating to the surface of the singulated semiconductor chip to produce a coated semiconductor chip. The process also includes a step of delivering the scanned and stored alignment pattern to an alignment and joining device positioned adjacent to and operatively associated with a substrate having a second electrical interconnect structure alignable to make electrical contact with the first electrical interconnect structure. The coated semiconductor chip is placed in the alignment and joining device so that when the scanned and stored alignment pattern is activated the alignment and joining device positions the coated semiconductor chip so that the first electrical interconnect structure is aligned to make electrical contact with the second electrical interconnect structure. This is followed by activating the alignment and joining device to join the coated semiconductor chip to the substrate so that the first electrical interconnect structure is in electrical contact with the second electrical interconnect structure. In one embodiment, the first electrical interconnect structure is placed on a surface of a semiconductor chip array in a wafer to produce the electrically connectable semiconductor structure which is followed by dicing to produce at least one of the singulated semiconductor chips. Another embodiment comprises aligning the fist and second electrical interconnect structures prior to applying the curable underfill coating. | 01-07-2010 |
20110034047 | Negative Thermal Expansion System (NTES) Device for TCE Compensation in Elastomer Composites and Conductive Elastomer Interconnects in Microelectronic Packaging - A method for fabricating a negative thermal expanding system device includes coating a wafer with a thermally decomposable polymer, patterning the decomposable polymer into repeating disk patterns, releasing the decomposable polymer from the wafer and forming a sheet of repeating patterned disks, suspending the sheet into a first solution with seeding compounds for electroless decomposition, removing the sheet from the first solution, suspending the sheet into a second solution to electrolessly deposit a first layer material onto the sheet, removing the sheet from the second solution, suspending the sheet into a third solution to deposit a second layer of material having a lower TCE value than the first layer of material, separating the patterned disks from one another, and annealing thermally the patterned disks to decompose the decomposable polymer and creating a cavity in place of the decomposable polymer. | 02-10-2011 |
20120045853 | SER Testing for an IC Chip Using Hot Underfill - A method for detecting soft errors in an integrated circuit (IC) due to transient-particle emission, the IC comprising at least one chip and a substrate includes mixing an epoxy with a radioactive source to form a hot underfill (HUF); underfilling the chip with the HUF; sealing the underfilled chip; measuring a radioactivity of the HUF at an edge of the chip; measuring the radioactivity of the HUF on a test coupon; testing the IC for soft errors by determining a current radioactivity of the HUF at the time of testing based on the measured radioactivity; and after the expiration of a radioactive decay period of the radioactive source, using the IC in a computing device by a user. | 02-23-2012 |
20130062740 | TUNABLE RADIATION SOURCE - An energy distribution of soft error-inducing radiation likely to be encountered by an electronic circuit during operation is determined. A tuned radiation source having a source energy distribution similar to the determined energy distribution is prepared. The electronic circuit is tested using the tuned radiation source. | 03-14-2013 |