Abstract: 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.

Abstract: Systems and methods for applying a thin layer of a liquid to the surface of a wafer with topography formed therein. The systems and methods include spreading a deposit of the liquid into a thin film on a wafer support, lowering the wafer onto the film, removing the wafer with an adhering layer of the film, positioning the wafer over a device wafer with the liquid film disposed between the wafers, curing the thin layer. The thin layer may be a UV adhesive which bonds the wafers upon exposure to UV light.

Abstract: 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.

Abstract: 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.

Abstract: 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.

Abstract: A material for bonding a first wafer to a second wafer, which includes an insulating adhesive with conductive particles embedded in the adhesive substance. When the adhesive is applied and melted or fused, and pressure is applied between the first wafer and the second wafer, the first wafer approaches the second wafer until a minimum separation is reached, defined by a dimension of the conductive particles. Each of the first wafer and the second wafer may have circuitry formed thereon, and the conductive particles may form a conductive path between the circuitry on one wafer and the circuitry on the other wafer. Advantageously, the high fusing temperature required by the insulating adhesive may also serve to activate a getter material, formed in the device cavity between the first wafer and the second wafer.

Abstract: 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.

Abstract: 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.

Abstract: 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.

Abstract: 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.

Abstract: A MEMS thermal switch is disclosed which couples a hot, expanding beam to a cool flexor beam using a slideably engaged tether, and bends the cool, flexor beam by the expansion of the hot beam. A rigidly engaged tether ties the distal ends of the hot, expanding beam and the cool, flexor beam together, whereas the slideably engaged tether allows the hot, expanding beam to elongate with respect to the cool, flexor beam, without loading the slideably engaged tether with a large shear force. As a result, the material of the tether can be made stiffer, and therefore transmit the bending force of the hot, expanding beam more efficiently to the cool, flexor beam.

Abstract: 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.

Abstract: A material for forming a conductive structure for a MEMS device is described, which is an alloy containing about 0.01% manganese and the remainder nickel. Data shows that the alloy possesses advantageous mechanical and electrical properties. In particular, the sheet resistance of the alloy is actually lower than the sheet resistance of the pure metal. In addition, the alloy may have superior creep and higher recrystallization temperature than the pure metal. It is hypothesized that these advantageous material properties are a result of the larger grain structure existing in the NiMn alloy film compared to the pure nickel metal film. These properties may make the alloy appropriate for applications such as MEMS thermal electrical switches for telecommunications applications.

Abstract: A material for bonding a lid wafer to a device wafer, which includes an adhesive substance with rigid particles embedded in the adhesive substance. The rigid particles may be particles or spheres of alumina, silica, or diamond, for example. The adhesive substance may be glass frit, epoxy, glue, cement or solder, for example. When the adhesive is applied and melted, and pressure is applied between the lid wafer and the device wafer, the lid wafer approaches the device wafer until a minimum separation is reached, which is defined by the rigid particles.

Abstract: A method for forming moveable features suspended over a substrate is described, wherein a cavity beneath the moveable feature is first formed using a liquid etchant applied through one or more release holes. After formation of the cavity, the outline of the moveable feature is formed using a dry etch process. Since the moveable feature is free to move upon its formation using the dry etch process, no stiction issues arise using the systems and methods described here.

Abstract: 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.

Abstract: 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.

Abstract: 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.

Abstract: A contact electrode for a device is made using an etching process to etch the surface of the contact electrode to form a corrugated contact surface wherein the outer edges of at least one grain is recessed from the outer edges of adjacent grains and is recessed by at least about 0.05 ?m from the contact plane. By having such a corrugated surface, the contact electrode is likely to contact another conductor with at least one pure metal grain. This etching treatment reduces contact resistance and contact resistance variability throughout many cycles of use of the contact electrode.

Abstract: A material for forming a conductive structure for a micromechanical current-driven device is described, which is an alloy containing about 0.025% manganese and the remainder nickel. Data shows that the alloy possesses advantageous mechanical and electrical properties. In particular, the sheet resistance of the alloy is actually lower and more stable than the sheet resistance of the pure metal. Accordingly, when used for conductive leads in a photonic device, the leads using the NiMn alloy may provide current to heat the photonic device while generating less heat within the leads themselves, and a more stable output.