Abstract: A thermoelectric heating/cooling device may include first and second thermally conductive headers. A plurality of thermoelectric elements thermally may be coupled in parallel between the first and second thermally conductive headers. In addition, a resistive heating element may be provided on the second header, and the second header may be between the resistive heating element and the plurality of thermoelectric elements.

Abstract: A method of fabricating a thermoelectric device includes providing a substrate having a plurality of inclined growth surfaces protruding from a surface thereof. Respective thermoelectric material layers are grown on the inclined growth surfaces, and the respective thermoelectric material layers coalesce to collectively define a continuous thermoelectric film. A surface of the thermoelectric film opposite the surface of the substrate may be substantially planar, and a crystallographic orientation of the thermoelectric film may be tilted at an angle of about 45 degrees or less relative to a direction along a thickness thereof. Related devices and fabrication methods are also discussed.

Abstract: A method of fabricating a thermoelectric device includes providing a substrate having a plurality of inclined growth surfaces protruding from a surface thereof. Respective thermoelectric material layers are grown on the inclined growth surfaces, and the respective thermoelectric material layers coalesce to collectively define a continuous thermoelectric film. A surface of the thermoelectric film opposite the surface of the substrate may be substantially planar, and a crystallographic orientation of the thermoelectric film may be tilted at an angle of about 45 degrees or less relative to a direction along a thickness thereof. Related devices and fabrication methods are also discussed.

Abstract: A thermoelectric device may include a thermoelectric element including a layer of a thermoelectric material and having opposing first and second surfaces. A first metal pad may be provided on the first surface of the thermoelectric element, and a second metal pad may be provided on the second surface of the thermoelectric element. In addition, the first and second metal pads may be off-set in a direction parallel with respect to the first and second surfaces of the thermoelectric element. Related methods are also discussed.

Abstract: A thermoelectric heating/cooling structure may include a heat exchanger and a heat spreader spaced apart from the heat exchanger. In addition, a plurality of spaced apart thermoelectric components may be thermally coupled in parallel between the heat exchanger and the heat spreader. More particularly, each of the thermoelectric components may include a first header adjacent the heat exchanger, a second header adjacent the heat spreader, and a plurality of thermoelectric elements thermally coupled in parallel between the first and second headers. The first headers of the thermoelectric components may be spaced apart adjacent the heat exchanger, and the second headers of the thermoelectric components may be spaced apart adjacent the heat spreader.

Abstract: An electronic assembly may include a packaging substrate, an integrated circuit (IC) semiconductor chip, a plurality of metal interconnection structures, and a thermoelectric heat pump. The integrated circuit (IC) semiconductor chip may have an active side including input/output pads thereon and a back side opposite the active side, and the IC semiconductor chip may be arranged with the active side facing the first surface of the packaging substrate. The plurality of metal interconnection structures may be between the active side of the IC semiconductor chip and the first surface of the packaging substrate, and the plurality of metal interconnection structures may provide mechanical connection between the active side of the IC semiconductor chip and the first surface of the packaging substrate. The thermoelectric heat pump may be coupled to the packaging substrate with the thermoelectric heat pump being configured to actively pump heat between the IC semiconductor chip and the packaging substrate.

Abstract: A thermoelectric device may include a thermoelectric element including a layer of a thermoelectric material and having opposing first and second surfaces. A first metal pad may be provided on the first surface of the thermoelectric element, and a second metal pad may be provided on the second surface of the thermoelectric element. In addition, the first and second metal pads may be off-set in a direction parallel with respect to the first and second surfaces of the thermoelectric element. Related methods are also discussed.

Abstract: An electronic assembly may include a packaging substrate, an integrated circuit (IC) semiconductor chip, a plurality of metal interconnection structures, and a thermoelectric heat pump. The integrated circuit (IC) semiconductor chip may have an active side including input/output pads thereon and a back side opposite the active side, and the IC semiconductor chip may be arranged with the active side facing the first surface of the packaging substrate. The plurality of metal interconnection structures may be between the active side of the IC semiconductor chip and the first surface of the packaging substrate, and the plurality of metal interconnection structures may provide mechanical connection between the active side of the IC semiconductor chip and the first surface of the packaging substrate. The thermoelectric heat pump may be coupled to the packaging substrate with the thermoelectric heat pump being configured to actively pump heat between the IC semiconductor chip and the packaging substrate.

Abstract: Three dimensional electronic and optical coupling devices that are capable of providing high speed coupling over a large frequency range while limiting the amount of space consumption in the communications network. An optical or electrical coupling device comprises a first substrate and a second substrate adjacent to the first substrate having one or more optical waveguides or microstrips formed thereon. The substrates will have disposed thereon conductive microstrips and/or dielectric elements. The one or more optical waveguides or microstrips formed on the first substrate correspond to at least one optical waveguides or microstrips formed on the second substrate so as to facilitate optical coupling between the corresponding waveguides. Precise spacing between the substrates and precise spacing between the optical waveguides or microstrips facilitate the requisite optical/RF coupling.

Abstract: Three dimensional electronic and optical coupling devices that are capable of providing high speed coupling over a large frequency range while limiting the amount of space consumption in the communications network. An optical or electrical coupling device comprises a first substrate and a second substrate adjacent to the first substrate having one or more optical waveguides or microstrips formed thereon. The substrates will have disposed thereon conductive microstrips and/or dielectric elements. The one or more optical waveguides or microstrips formed on the first substrate correspond to at least one optical waveguides or microstrips formed on the second substrate so as to facilitate optical coupling between the corresponding waveguides. Precise spacing between the substrates and precise spacing between the optical waveguides or microstrips facilitate the requisite optical/RF coupling.

Abstract: Three dimensional electronic and optical coupling devices that are capable of providing high speed coupling over a large frequency range while limiting the amount of space consumption in the communications network. An optical or electrical coupling device comprises a first substrate and a second substrate adjacent to the first substrate having one or more optical waveguides or microstrips formed thereon. The substrates will have disposed thereon conductive microstrips and/or dielectric elements. The one or more optical waveguides or microstrips formed on the first substrate correspond to at least one optical waveguides or microstrips formed on the second substrate so as to facilitate optical coupling between the corresponding waveguides. Precise spacing between the substrates and precise spacing between the optical waveguides or microstrips facilitate the requisite optical/RF coupling.

Abstract: Three dimensional electronic and optical coupling devices that are capable of providing high speed coupling over a large frequency range while limiting the amount of space consumption in the communications network. An optical or electrical coupling device comprises a first substrate and a second substrate adjacent to the first substrate having one or more optical waveguides or microstrips formed thereon. The substrates will have disposed thereon conductive microstrips and/or dielectric elements. The one or more optical waveguides or microstrips formed on the first substrate correspond to at least one optical waveguides or microstrips formed on the second substrate so as to facilitate optical coupling between the corresponding waveguides. Precise spacing between the substrates and precise spacing between the optical waveguides or microstrips facilitate the requisite optical/RF coupling.

Abstract: A microelectromechanical system (MEMS) tunable capacitor having low loss and a corresponding high Q is provided. The tunable capacitor includes a first substrate having a first capacitor plate disposed thereon. A fixed pivot structure is disposed on the first surface of the first substrate, proximate the first capacitor plate. The fixed pivot structure as a point of attachment for a flexible membrane that extends outward from the fixed pivot and generally overlies the first capacitor plate. A second substrate is attached to the underside of the flexible membrane and a second capacitor plate is disposed thereon such that the first and second capacitor plates face one another in a spaced apart relationship. A MEMS actuator is operably in contact with the flexible membrane for the purpose of providing an actuation force to the flexible membrane, thereby varying the capacitance between the first and second capacitor plates.

Abstract: A reflector having a mechanically deformable portion of at least one reflective surface is disclosed. By deforming the portion of the reflective surface, discontinuity is introduced in that portion of the reflective surface. The discontinuity in the reflective surface scatters incident radiation signals so as to cause attenuation in the reflected signal. By selectively deforming the portion of the reflective surface, the reflected signal can be modulated to encode data thereon. The mechanically deformable portion of the reflective surface preferably comprises plates integrally formed therein.

Abstract: A reflector having a mechanically deformable portion of at least one reflective surface is disclosed. By deforming the portion of the reflective surface, discontinuity is introduced in that portion of the reflective surface. The discontinuity in the reflective surface scatters incident radiation signals so as to cause attenuation in the reflected signal. By selectively deforming the portion of the reflective surface, the reflected signal can be modulated to encode data thereon. The mechanically deformable portion of the reflective surface preferably comprises plates integrally formed therein.

Abstract: Microelectronic packages are formed wherein solder bumps on one or more substrates are expanded, to thereby extend and contact the second substrate and form a solder connection. The solder bumps are preferably expanded by reflowing additional solder into the plurality of solder bumps. The additional solder may be reflowed from an elongated, narrow solder-containing region adjacent the solder bump, into the solder bump. After reflow, the solder bump which extends across a pair of adjacent substrates forms an arched solder column or partial ring of solder between the two substrates.

Abstract: Microelectronic packages are formed wherein solder bumps on one or more substrates are expanded, to thereby extend and contact the second substrate and form a solder connection. The solder bumps are preferably expanded by reflowing additional solder into the plurality of solder bumps. The additional solder may be reflowed from an elongated, narrow solder-containing region adjacent the solder bump, into the solder bump. After reflow, the solder bump which extends across a pair of adjacent substrates forms an arched solder column or partial ring of solder between the two substrates.