Innovative Micro Technology Patent applications |
Patent application number | Title | Published |
20160126696 | MICROFABRICATED OPTICAL APPARATUS - A microfabricated optical apparatus that includes a light source driven by a waveform, a turning mirror, and a beam shaping element, wherein the waveform is delivered to the light source by at least one through silicon via. | 05-05-2016 |
20160093531 | METHOD FOR FORMING THROUGH SUBSTRATE VIAS WITH TETHERS - A method for forming through silicon vias (TSVs) in a silicon substrate is disclosed. The method involves forming a silicon post as an substantially continuous annulus in a first side of a silicon substrate, removing material from an opposite side to the level of the substantially continuous annulus, removing the silicon post and replacing it with a metal material to form a metal via extending through the thickness of the substrate. The substantially continuous annulus may be interrupted by at least one tether which connects the silicon post to the silicon substrate. The tether may be formed of a thing isthmus of silicon, or some suitable insulating material. | 03-31-2016 |
20160093530 | METHOD FOR FORMING THROUGH SUBSTRATE VIAS - A method for forming through silicon vias (TSVs) in a silicon substrate is disclosed. The method involves forming a silicon post as an annulus in a first side of a silicon substrate, removing material from an opposite side to the level of the annulus, removing the silicon post and replacing it with a metal material to form a metal via extending through the thickness of the substrate. | 03-31-2016 |
20160042902 | SOLDER BUMP SEALING METHOD AND DEVICE - A method for forming a cavity in a microfabricated structure, includes the sealing of that cavity with a low temperature solder. The method may include forming a sacrificial layer over a substrate, forming a flexible membrane over the sacrificial layer, forming a release hole through a flexible membrane to the sacrificial layer, introducing an etchant through the release hole to remove the sacrificial layer, and then sealing that release hole with a low temperature solder. | 02-11-2016 |
20150266726 | WAFER LEVEL HERMETIC BOND USING METAL ALLOY WITH RAISED FEATURE AND WETTING LAYER - Systems and methods for forming an encapsulated device include a substantially hermetic seal which seals a device in an environment between two substrates. The substantially hermetic seal is formed by an alloy of two metal layers, one having a lower melting temperature than the other. The metal layers may be deposited two substrates, along with a raised feature formed under at least one of the metal layers. The two metals may form an alloy of a predefined stoichiometry in at least two locations on either side of the midpoint of the raised feature. The formation of the alloy may be improved by the use of an organic wetting layer adjacent to the lower melting temperature metal. Design guidelines are set forth for reducing or eliminating the leakage of molten metal into the areas adjacent to the bondlines. | 09-24-2015 |
20150183630 | DEVICE USING GLASS SUBSTRATE ANODIC BONDING - A bonding technology is disclosed that can form an anodic, conductive bond between two optically transparent substrates. The anodic bond may be accompanied by a metal alloy, solder, eutectic and polymer bond. The first anodic bond may provide one attribute such as hermeticity, whereas the second bond may provide another attribute, such as electrical conductivity. | 07-02-2015 |
20150183200 | METHOD USING GLASS SUBSTRATE ANODIC BONDING - A bonding technology is disclosed that can form an anodic, conductive bond between two optically transparent substrates. The anodic bond may be accompanied by a metal alloy, solder, eutectic and polymer bond. The first anodic bond may provide one attribute such as hermeticity, whereas the second bond may provide another attribute, such as electrical conductivity. | 07-02-2015 |
20150069618 | Method for forming through wafer vias - A method for forming through substrate vias (TSVs) in a non-conducting, glass substrate is disclosed. The method involves patterning a silicon template substrate with a plurality of lands and spaces, bonding a slab or wafer of glass to the template substrate, and melting the glass so that it flows into the spaces formed in the template substrate. The template substrate may then be removed to leave a plurality of TSVs in the glass slab or wafer. | 03-12-2015 |
20150031120 | MEMS PARTICLE SORTING ACTUATOR AND METHOD OF MANUFACTURE - A MEMS-based system and a method are described for separating a target particle from the remainder of a fluid stream. The system makes use of a unique, microfabricated movable structure formed on a substrate, which moves in a rotary fashion about one or more fixed points, which are all located on one side of the axis of motion. The movable structure is actuated by a separate force-generating apparatus, which is entirely separate from the movable structure formed on its substrate. This allows the movable structure to be entirely submerged in the sample fluid. | 01-29-2015 |
20150028863 | Microfabricated magnetic field transducer with flux guide - A microfabricated magnetic field transducer uses a magnetically sensitive structure in combination with one or more permeable magnetic flux guides. The flux guides may route off-axis components of an externally applied magnetic field across the sensitive axis of the magnetically sensitive structure, or may shield the magnetically sensitive structure from off-axis, stray fields or noise sources. A combination of flux guides and magnetically sensitive structures arranged on a single substrate may enable an integrated, 3-axis magnetometer in a single package, greatly improving cost and performance. | 01-29-2015 |
20140034555 | Particle manipulation system with cytometric capability - A MEMS-based particle manipulation system which uses a particle manipulation stage and a plurality of laser interrogation regions. The laser interrogation regions may be used to assess the effectiveness or accuracy of the particle manipulation stage. In one exemplary embodiment, the particle manipulation stage is a microfabricated, flap-type fluid valve, which sorts a target particle from non-target particles in a fluid stream. The laser interrogation stages are disposed in the microfabricated fluid channels at the input and output of the flap-type sorting valve. The laser interrogation regions may be used to assess the effectiveness or accuracy of the sorting, and to control or adjust sort parameters during the sorting process. | 02-06-2014 |
20130199730 | Wafer bonding chamber with dissimilar wafer temperatures - A wafer bonding chamber is disclosed, which maintains two wafers to be bonded together at two substantially different temperatures. A lid wafer may be held at a higher temperature than a device wafer, as the device wafer may have delicate structures formed thereon, which cannot withstand higher temperatures. The lid wafer may have an adhesive bonding material formed thereon, which is melted or cured at the higher temperature. The temperature differential may be maintained by applying at least one of a heating mechanism and a cooling mechanism preferentially to one of the wafers to be bonded in the wafer bonding chamber. | 08-08-2013 |
20120319303 | Wafer level hermetic bond using metal alloy with keeper layer - Systems and methods for forming an encapsulated device include a hermetic seal which seals an insulating environment between two substrates, one of which supports the device. The hermetic seal is formed by an alloy of two metal layers, one deposited on a first substrate and the other deposited on the second substrate. At least one of the substrates may include a raised feature formed under at least one of the metal layers. The two metals may for an alloy of a predefined stoichiometry in at least two locations on either side of the midpoint of the raised feature. This alloy may have advantageous features in terms of density, mechanical, electrical or physical properties that may improve the hermeticity of the seal, for example. | 12-20-2012 |
20120302946 | Microfabricated electromagnetic actuator with push-pull motion - A micromechanical electromagnetic actuator may have two separate components: a flux-generating portion and a separate movable structure. The flux-generating portion may have a plurality of conductive coils wound around a magnetically permeable material. Each coil generates a magnetic field along its axis, which is different for each of the coils. The adjacent movable structure may include magnetically permeable features, one inlaid in the movable structure and other stationary features which focus the flux produced by the flux-generating mechanism across a gap between the stationary features. By energizing each coil sequentially, a push-pull motion in the actuator may result from the force of the magnetically permeable features. This push-pull actuator may be particularly effective when used as a pumping element in a drug delivery system, or other fluidic pumping system. | 11-29-2012 |
20120255373 | Multistage cartridge for MEMS particle storing system - A disposable cartridge is described which is equipped with a plurality of microfabricated particle sorting structures. The disposable cartridge may include passageways which connect fluid reservoirs in the cartridge with corresponding microfluidic passageways on the particle sorting structure. A flexible gasket may prevent leakages and allow the fluid to cross the gasket barrier through a plurality of holes in the gasket, allowing fluid to be transferred from the reservoirs to the microfabricated particle sorting structures. The plurality of particle sorting structures may be arranged in the disposable cartridge in order to perform multiple separation operations, such as a sequential or parallel sorting operation. | 10-11-2012 |
20120190105 | Cartridge for MEMS particle sorting system - A disposable cartridge is described which is compatible with a MEMS particle sorting device. The disposable cartridge may include passageways which connect fluid reservoirs in the cartridge with corresponding microfluidic passageways on the MEMS chip. A flexible gasket may prevent leakages and allow the fluid to cross the gasket barrier through a plurality of holes in the gasket. Vents and septums may also be included to allow air to escape and fluids to be inserted by hypodermic needle. A MEMS-based particle sorting system using the disposable cartridge is also described. | 07-26-2012 |
20120190104 | MEMS Particle sorting actuator and method of manufacturing - A MEMS-based system and a method are described for separating a target particle from the remainder of a fluid stream. The system makes use of a unique, microfabricated movable structure formed on a substrate, which moves in a rotary fashion about one or more fixed points, which are all located on one side of the axis of motion. The movable structure is actuated by a separate force-generating apparatus, which is entirely separate from the movable structure formed on its substrate. This allows the movable structure to be entirely submerged in the sample fluid. | 07-26-2012 |
20120164718 | Removable/disposable apparatus for MEMS particle sorting device - A micromechanical particle sorting system uses a removable/disposable apparatus which may include a compressible device, a filter apparatus and a cell sorter chip assembly. The chip assembly may include a tubing strain relief manifold and a microfabricated cell sorting chip. The chip assembly may be detachable from the filter apparatus in order to mount the MEMS particle sorting chip adjacent to a force-generating apparatus which resides with the particle sorting system. A disturbance device installed in the particle sorting system may interact with a transducer on the removable/disposable apparatus to reduce clogging of the flow through the system. Using this removable/disposable apparatus, when the sample is changed, the entire apparatus can be thrown away with minimal expense and system down time. | 06-28-2012 |
20120132522 | Deposition/bonding chamber for encapsulated microdevices and method of use - A method for depositing a getter for encapsulation in a device cavity containing a microdevice comprises depositing the getter material while the device wafer and lid wafer are enclosed in a bonding chamber. A plasma sputtering process may be used, wherein by applying a large negative voltage to the lid wafer, a plasma is formed in the low pressure environment within the bonding chamber. The plasma then sputters the getter material from a getter target, and this getter material is directly thereafter sealed within the device cavity of the microdevice, all within the deposition/bonding chamber. | 05-31-2012 |
20120080762 | Plating process and apparatus for through wafer features - A method for forming through features in a substrate uses a seed layer deposited over a first substrate, and a second substrate bonded to the seed layer. The features may be formed in the first substrate, by plating a conductive filler material onto the seed layer. The first substrate and the second substrate may then be bonded to a third substrate, and the second substrate is removed, leaving through features and first substrate adhered to the third substrate. The through features may provide at least one of electrical access and motion to a plurality of devices formed on the third substrate, or may impart movement to a moveable feature on the first substrate, wherein the third substrate supports the first substrate after removal of the second substrate. | 04-05-2012 |
20120068300 | Inductive getter activation for high vacuum packaging - An approach to activating a getter within a sealed vacuum cavity is disclosed. The approach uses inductive coupling from an external coil to a magnetically permeable material deposited in the vacuum cavity. The getter material is formed over this magnetically permeable material, and heated specifically thereby, leaving the rest of the device cavity and microdevice relatively cool. Using this inductive coupling technique, the getter material can be activated after encapsulation, and delicate structures and low temperature wafer bonding mechanisms may be used. | 03-22-2012 |
20120015456 | SYSTEM AND METHOD FOR PROVIDING ACCESS TO AN ENCAPSULATED DEVICE - A method for providing access to a feature on a device wafer, and located outside an encapsulation region is described. The method includes forming a cavity in the lid wafer, aligning the lid wafer with the device wafer so that the cavity is located substantially above the feature, and removing material substantially uniformly from the bottom surface of the lid wafer, until an aperture is formed at the cavity, over the feature on the device wafer. By removing material from the lid wafer in a substantially uniform manner, difficulties with the prior art procedure of saw cutting, such as alignment and debris generation, are avoided. | 01-19-2012 |
20110295229 | In-plane electromagnetic mems pump - A micromechanical pumping system is formed on a substrate surface. The pumping system uses a pumping element which pumps a fluid through valves which move in a plane substantially parallel to the substrate surface. An electromagnetic actuating mechanism may also be fabricated on the surface of the substrate. Magnetic flux produced by a coil around a permeable core may be coupled to a permeable member affixed to a pumping element. The permeable member and pumping element may be configured to move in a plane parallel to the substrate. The electromagnetic actuating mechanism gives the pumping system a large throw and substantial force, such that the fluid pumped by the pumping system may be pumped through a transdermal cannula to deliver a therapeutic substance to the tissue underlying the skin of a patient. | 12-01-2011 |
20110250092 | Inlaid optical material and method of manufacture - An optical material is inlaid into a supporting substrate, with the top surface of the optical material flush with the top surface of the substrate, wherein the optical element is used to shape a beam of light travelling substantially parallel to the top surface of the substrate, but with the central axis of the beam below the top surface of the substrate. The optical elements serve to shape the beam of light for delivery to or from a microfabricated structure within the device. | 10-13-2011 |
20110155548 | Dual substrate MEMS plate switch and method of manufacture - Systems and methods for forming an electrostatic MEMS plate switch include forming a deformable plate on a first substrate, forming the electrical contacts on a second substrate, and coupling the two substrates using a hermetic seal. The deformable plate may have at least one shunt bar located at a nodal line of a vibrational mode of the deformable plate, so that the shunt bar remains relatively stationary when the plate is vibrating in that vibrational mode. A hermetic seal may be made around the device with a larger, secondary enclosure. Electrical access to the deformable plate may be accomplished by an electrical path which is independent of the seal. The electrical path may include a via through the first substrate or the second substrate, or a flash deposited on an external region of the switch. | 06-30-2011 |
20110130721 | Configurable power supply using MEMS switch - Systems and methods for forming a configurable power supply uses a plurality of dual substrate MEMS switches to couple a plurality of power cells to provide a selectable, or variable, output voltage. The same circuit may output two different voltages to power two different circuits of the device, or may distribute the load evenly amongst the cells. Thus, the configurable power supply may extend the lifetime and improve the reliability of the device, or decrease its weight, size and cost. | 06-02-2011 |
20110024923 | Wafer level hermetic bond using metal alloy with keeper layer - Systems and methods for forming an encapsulated device include a hermetic seal which seals an insulating environment between two substrates, one of which supports the device. The hermetic seal is formed by an alloy of two metal layers, one deposited on a first substrate and the other deposited on the second substrate. At least one of the substrates may include a raised feature formed under at least one of the metal layers. One of the metal layer may have a diffusion barrier layer and a “keeper” layer formed thereover, wherein the keeper layers keeps the metal confined to a particular area. By using such a “keeper” layer, the substrate components may be heated to clean their surfaces, without activating or spending the bonding mechanism. | 02-03-2011 |
20100018021 | Hysteretic MEMS two-dimensional thermal device and method of manufacture - A MEMS hysteretic thermal device may be formed having two passive beam segments driven by a current-carrying loop coupled to the surface of a substrate. The first beam segment is configured to move in a direction having a component perpendicular to the substrate surface, whereas the second beam segment is configured to move in a direction having a component parallel to the substrate surface. By providing this two-dimensional motion, a single MEMS hysteretic thermal device may by used to close a switch having at least one stationary contact affixed to the substrate surface. | 01-28-2010 |
20100003772 | Wafer level hermetic bond using metal alloy with raised feature - Systems and methods for forming an encapsulated device include a hermetic seal which seals an insulating environment between two substrates, one of which supports the device. The hermetic seal is formed by an alloy of two metal layers, one deposited on a first substrate and the other deposited on the second substrate, along with a raised feature formed on the first or the second substrate. At least one of the metal layers may be deposited conformally over the raised feature. The raised feature penetrates the molten material of the first or the second metal layers during formation of the alloy, and produces a spectrum of stoichiometries for the formation of the desired alloy, as a function of the distance from the raised feature. At some distance from the raised feature, the proper ratio of the first metal to the second metal exists to form an alloy of the preferred stoichiometry. | 01-07-2010 |
20090201119 | Hysteretic mems thermal device and method of manufacture - A MEMS hysteretic thermal actuator may have a plurality of beams disposed over a heating element formed on the surface of the substrate. The plurality of beams may be coupled to a passive beam which is not disposed over the heating element. One of the plurality of beams may be formed in a first plane parallel to the substrate, whereas another of the plurality of beams may be formed in a second plane closer to the surface of the substrate. When the heating element is activated, it heats the plurality of beams such that they move the passive beam in a trajectory that is neither parallel to nor perpendicular to the surface of the substrate. When the beams are cooled, they may move in a different trajectory, approaching the substrate before moving laterally across it to their initial positions. By providing one electrical contact on the distal end of the passive beam and another stationary electrical contact on the substrate surface, the MEMS hysteretic actuator may form a reliable electrical switch that is relatively simple to manufacture and operate. | 08-13-2009 |
20090181488 | MEMS thermal actuator and method of manufacture - A separated MEMS thermal actuator is disclosed which is largely insensitive to creep in the cantilevered beams of the thermal actuator. In the separated MEMS thermal actuator, a inlaid cantilevered drive beam formed in the same plane, but separated from a passive beam by a small gap. Because the inlaid cantilevered drive beam and the passive beam are not directly coupled, any changes in the quiescent position of the inlaid cantilevered drive beam may not be transmitted to the passive beam, if the magnitude of the changes are less than the size of the gap. | 07-16-2009 |
20090053855 | Indented lid for encapsulated devices and method of manufacture - A method for providing improved gettering in a vacuum encapsulated device is described. The method includes forming a plurality of small indentation features in a device cavity formed in a lid wafer. The gettering material is then deposited over the indentation features. The indentation features increase the surface area of the getter material, thereby increasing the volume of gas that the getter material can absorb. This may improve the vacuum maintained within the vacuum cavity over the lifetime of the vacuum encapsulated device. | 02-26-2009 |
20090023244 | Etching/bonding chamber for encapsulated devices and method of use - A method for activating a getter at low temperature for encapsulation in a device cavity containing a microdevice comprises etching a passivation layer off the getter material while the device wafer and lid wafer are enclosed in a bonding chamber. A plasma etching process may be used, wherein by applying a large negative voltage to the lid wafer, a plasma is formed in the low pressure environment within the bonding chamber. The plasma then etches the passivation layer from the getter material, which is directly thereafter sealed within the device cavity of the microdevice, all within the etching/bonding chamber. | 01-22-2009 |
20090001537 | Gettering material for encapsulated microdevices and method of manufacture - A method for providing improved gettering in a vacuum encapsulated microdevice is described. The method includes designing a getter alloy to more closely approximate the coefficient of thermal expansion of a substrate upon which the getter alloy is deposited. Such a getter alloy may have a weight percentage of less than about 8% iron (Fe) and greater than about 50% zirconium, with the balance being vanadium and titanium, which may better match the coefficient of thermal expansion of a silicon substrate. In one exemplary embodiment, the improved getter alloy is deposited on a silicon substrate prepared with a plurality of indentation features, which increase the surface area of the substrate exposed to the vacuum. Such a getter alloy is less likely to delaminate from the indented surface of the substrate material during heat-activated steps, such as activating the getter material and bonding a lid wafer to the device wafer supporting the microdevice. | 01-01-2009 |
20080318349 | Wafer level hermetic bond using metal alloy - Systems and methods for forming an encapsulated MEMS device include a hermetic seal which seals an insulating gas between two substrates, one of which supports the MEMS device. The hermetic seal may be formed by heating at least two metal materials, in order to melt at least one of the metal materials. The first melted metal material flows into and forms an alloy with a second metal material, forming a hermetic seal which encapsulates the MEMS device. | 12-25-2008 |
20080278268 | Dual substrate MEMS plate switch and method of manufacture - Systems and methods for forming an electrostatic MEMS plate switch include forming a deformable plate on a first substrate, forming the electrical contacts on a second substrate, and coupling the two substrates using a hermetic seal. The deformable plate may have at least one shunt bar located at a nodal line of a vibrational mode of the deformable plate, so that the shunt bar remains relatively stationary when the plate is vibrating in that vibrational mode. The hermetic seal may be a gold/indium alloy, formed by heating a layer of indium plated over a layer of gold. Electrical access to the electrostatic MEMS switch may be made by forming vias through the thickness of the second substrate. | 11-13-2008 |
20080277672 | Lid structure for microdevice and method of manufacture - A system and a method are described for forming features at the bottom of a cavity in a substrate. Embodiments of the systems and methods provide an infrared transmitting, hermetic lid for a microdevice. The lid may be manufactured by first forming small, subwavelength features on a surface of an infrared transmitting substrate, and coating the subwavelength features with an etch stop material. A spacer wafer is then bonded to the infrared transmitting substrate, and a device cavity is etched into the spacer wafer down to the etch stop material, exposing the subwavelength features. The etch stop material may then be removed, and the microdevice enclosed in the device cavity, by bonding the device wafer to the lid. | 11-13-2008 |
20080277258 | MEMS plate switch and method of manufacture - Systems and methods for forming an electrostatic MEMS plate switch include forming a deformable plate on a first substrate, forming the electrical contacts on a second substrate, and coupling the two substrates using a hermetic seal. The deformable plate may have a flexible shunt bar which has one end coupled to the deformable plate, and the other end coupled to a contact on the second substrate. Upon activating the switch, the deformable plate urges the shunt bar against a second contact formed in the second substrate, thereby closing the switch. The hermetic seal may be a gold/indium alloy, formed by heating a layer of indium plated over a layer of gold. Electrical access to the electrostatic MEMS switch may be made by forming vias through the thickness of the second substrate. | 11-13-2008 |
20080250785 | Micromechanical device with gold alloy contacts and method of manufacture - A MEMS switch device is made using a gold alloy as the switch contact material. The increased mechanical hardness of the alloy compared to the pure gold prevents the contacts of the switch from welding together. A scrubbing action which occurs when the switch closes may allow the contact surfaces to come to rest where their surfaces are complementary, thus resulting in higher contact area and low contact resistance, despite the higher sheet resistance of the gold alloy material relative to the pure gold material. | 10-16-2008 |