Patent application number | Description | Published |
20120096813 | Incident Radiation Detector Packaging - In accordance with particular embodiments, a method for packaging an incident radiation detector includes depositing an opaque solder resistant material on a first surface of a transparent lid substrate configured to cover at least one detector. The method also includes forming at least one cavity in the lid substrate. The method further includes forming a first portion of at least one hermetic seal ring on the opaque solder resistant material. The first portion of each hermetic seal ring surrounds a perimeter of a corresponding cavity in the lid substrate. The method also includes aligning the first portion of the at least one hermetic seal ring with a second portion of the at least one hermetic seal ring. The method additionally includes bonding the first portion of the at least one hermetic seal ring with the second portion of the at least one hermetic seal ring with solder. | 04-26-2012 |
20120111925 | Reducing Formation Of Oxide On Solder - In certain embodiments, a system includes a deposition system and a plasma/bonding system. The deposition system deposits a solder outwardly from a substrate of a number of substrates. The plasma/bonding system comprises a plasma system configured to plasma clean the substrate and a bonding system configured to bond the substrates. The plasma/bonding system at least reduces reoxidation of the solder. In certain embodiments, a method comprises depositing solder outwardly from a substrate, removing metal oxide from the substrate, and depositing a capping layer outwardly from the substrate to at least reduce reoxidation of the solder. | 05-10-2012 |
20120127579 | Protecting An Optical Surface - According to one embodiment, a method includes receiving a light beam at an anti-reflective layer of optically transmissive material. The anti-reflective layer has an outer surface disposed within a recess of a protective layer of optically transmissive material, such that the outer surface is protected by the recess and the protective layer from being contacted. The outer surface is further disposed along an optical path of an optical device disposed inwardly from the outer surface. The anti-reflective layer has an average cross-sectional thickness that is less than an average cross-sectional thickness of the protective layer. The method further includes modulating the light beam using the anti-reflective layer. | 05-24-2012 |
20120139072 | Wafer Level Packaged Focal Plane Array - A method for manufacturing a wafer level packaged focal plane array, in accordance with certain embodiments, includes forming a detector wafer, which may include forming detector arrays and read-out circuits. The method may also include forming a lid wafer. Forming the lid wafer may include polishing a surface of a magnetically confined Czochralski (MCZ) wafer, bonding a Czochralski wafer to the MCZ wafer, and forming pockets in the Czochralski wafer. Each pocked may expose a portion of the polished surface of the MCZ wafer. The method may further include bonding the lid wafer and the detector wafer together such that the each detector array and read-out circuit are sealed within a different pocket, thereby forming a plurality of wafer level packaged focal plane arrays. The method may additionally include separating at least one wafer level packaged focal plan array from the plurality of wafer level packaged focal plane arrays. | 06-07-2012 |
20140053966 | METHOD OF STRESS RELIEF IN ANTI-REFLECTIVE COATED CAP WAFERS FOR WAFER LEVEL PACKAGED INFRARED FOCAL PLANE ARRAYS - Methods for reducing wafer bow induced by an anti-reflective coating of a cap wafer are provided. The method may utilize a shadow mask having at least one opening therein that is positioned opposite recessed regions in a cap wafer. The method may further include depositing at least one layer of an anti-reflective coating material through the shadow mask onto a planar side of a cap wafer to provide a discontinuous coating on the planar side. | 02-27-2014 |
20150076216 | REDUCING FORMATION OF OXIDE ON SOLDER - In certain embodiments, a system includes a deposition system and a plasma/bonding system. The deposition system deposits a solder outwardly from a substrate of a number of substrates. The plasma/bonding system comprises a plasma system configured to plasma clean the substrate and a bonding system configured to bond the substrates. The plasma/bonding system at least reduces reoxidation of the solder. In certain embodiments, a method comprises depositing solder outwardly from a substrate, removing metal oxide from the substrate, and depositing a capping layer outwardly from the substrate to at least reduce reoxidation of the solder. | 03-19-2015 |
Patent application number | Description | Published |
20140124899 | INTEGRATED BONDLINE SPACERS FOR WAFER LEVEL PACKAGED CIRCUIT DEVICES - A method of forming a wafer level packaged circuit device includes forming a device wafer, the device wafer including a first group of one or more material layers left remaining in a first region of a substrate of the device wafer; and forming a cap wafer configured to be attached to the device wafer, the cap wafer including a second group of one or more material layers left remaining in a second region of a substrate of the cap wafer; wherein a combined thickness of the first and second groups of one or more material layers defines an integrated bond gap control structure upon bonding of the device wafer and the cap wafer. | 05-08-2014 |
20140175590 | GETTER STRUCTURE FOR WAFER LEVEL VACUUM PACKAGED DEVICE - A wafer level vacuum packaged (WLVP) device having a first substrate having an array of detectors and a second substrate bonded to the first substrate having a plurality of protrusions and a plurality of getter material members projecting outwardly from a sidewall of the protrusions members are disposed at oblique angles to the sidewalls and have ends extending into gaps between the protrusions. The device is formed by: forming protrusions into a surface of a substrate; and depositing getter material by physical vapor deposition from an evaporating source of the getter material at an oblique angle to the sidewalls, atoms of the getter material initially forming nucleation sites on the sidewalls with subsequent atoms attaching to the nucleation sites and shadowing area surrounding each nucleation site, the getter material thereby growing into structures towards the evaporating source. | 06-26-2014 |
20140193948 | INTEGRATED BONDLINE SPACERS FOR WAFER LEVEL PACKAGED CIRCUIT DEVICES - A method of forming a wafer level packaged circuit device includes forming a device wafer, the device wafer including a first group of one or more material layers left remaining in a first region of a substrate of the device wafer; and forming a cap wafer configured to be attached to the device wafer, the cap wafer including a second group of one or more material layers left remaining in a second region of a substrate of the cap wafer; wherein a combined thickness of the first and second groups of one or more material layers defines an integrated bond gap control structure upon bonding of the device wafer and the cap wafer. | 07-10-2014 |
20140346643 | INTEGRATED BONDLINE SPACERS FOR WAFER LEVEL PACKAGED CIRCUIT DEVICES - A method of forming a wafer level packaged circuit device includes forming a device wafer, the device wafer including a first group of one or more material layers left remaining in a first region of a substrate of the device wafer; and forming a cap wafer configured to be attached to the device wafer, the cap wafer including a second group of one or more material layers left remaining in a second region of a substrate of the cap wafer; wherein a combined thickness of the first and second groups of one or more material layers defines an integrated bond gap control structure upon bonding of the device wafer and the cap wafer. | 11-27-2014 |
20150014854 | WAFER LEVEL PACKAGE SOLDER BARRIER USED AS VACUUM GETTER - An electronic device and methods of manufacture thereof. One or more methods may include providing a lid wafer having a cavity and a surface surrounding the cavity and a device wafer having a detector device and a reference device. In certain examples, a solder barrier layer of titanium material may be deposited onto the surface of the lid wafer. The solder barrier layer of titanium material may further be activated to function as a getter. In various examples, the lid wafer and the device wafer may be bonded together using solder, and the solder barrier layer of titanium material may prevent the solder from contacting the surface of the lid wafer. | 01-15-2015 |