Abstract: Embodiments of an apparatus and method for sealing and cutting of tissue during surgeries, especially in general, endoscopic, laparoscopic and robotic, are described. In one aspect, an apparatus comprises a laser system and a laser beam delivery unit. The laser system comprises a tissue cutting laser configured to emit a first laser beam to cut a tissue. The laser system also comprises a tissue sealing laser configured to emit a second laser beam to seal the tissue. The laser beam delivery unit is detachably coupled to the laser system and is configured to guide and direct the first and second laser beams to cut and seal the tissue.

Abstract: Embodiments of an apparatus and method for sealing and cutting of tissue during surgeries, especially in general, endoscopic, laparoscopic and robotic, are described. In one aspect, an apparatus comprises a laser system and a laser beam delivery unit. The laser unit is configured to emit a laser beam suitable for tissue sealing and cutting. The laser beam delivery unit is detachably coupled to the laser unit, and is configured to guide and direct the laser beam to seal and cut tissue. Use of optical fiber guided sensors described herein further enhances the safety and efficacy of the apparatus.

Abstract: Embodiments of an apparatus and method for sealing of tissue during uncontrollable bleeding situations during surgery are described. In one aspect, an apparatus comprises a laser unit, a laser beam delivery unit, and at least one sensor coupled to the probe of the laser beam delivery unit. The at least one sensor is configured to sense a parameter associated with the tissue or the probe. The laser unit is configured to emit a laser beam suitable for sealing an opening on a tissue. The laser beam delivery unit is detachably coupled to the laser unit, and is configured to guide and direct the laser beam to seal the opening on the tissue.

Abstract: In one aspect, an apparatus comprises a substrate, a first electrically-driven device disposed on the substrate, a second electrically-driven device disposed on the substrate, and a composite heat sink device. The composite heat sink device comprises a first thermal conduction member, a second thermal conduction member, and a thermal insulation member. The first thermal conduction member is disposed on the first electrically-driven device such that at least a portion of the heat generated by the first electrically-driven device is transferred to the first thermal conduction member by conduction. The second thermal conduction member is disposed on the second electrically-driven device such that at least a portion of the heat generated by the second electrically-driven device is transferred to the second thermal conduction member by conduction. The thermal insulation member is disposed between and thermally decouples the first thermal conduction member and the second thermal conduction member from one another.

Abstract: A thermal energy storage apparatus that absorbs thermal energy from a heat-generating device is described. In one aspect, the thermal energy storage apparatus comprises a non-metal container and a phase-change material. The non-metal container is configured to receive the heat-generating device thereon. The phase-change material is contained in the non-metal container and configured to absorb at least a portion of heat from the heat-generating device through the non-metal container.

Abstract: Various embodiments of an apparatus that simultaneously cools and thermally decouples adjacent electrically-driven devices in close proximity are provided. In one aspect, an apparatus comprises a first non-silicon heat sink and a first silicon-based heat sink disposed on the first non-silicon heat sink. The first silicon-based heat sink is configured to receive a first electrically-driven device on a first portion of the first silicon-based heat sink and to receive a second electrically-driven device on a second portion of the first silicon-based heat sink. The first silicon-based heat sink includes a first groove or a first opening between the first portion and the second portion such that a heat conduction path between the first electrically-driven device and the first non-silicon heat sink through the first silicon-based heat sink is shorter than a heat conduction path between the first electrically-driven device and the second electrically-driven device through the first silicon-based heat sink.

Abstract: A direct refrigeration cooling platform can cool high heat density sources such as LEDs, IC chip, power amplifiers and laser diodes. The platform utilizes a combination of technologies from a water cooled cold plate design and a vapor compression refrigeration system. The cold plate of the direct refrigeration cooling platform replaces an evaporator in a conventional vapor compression refrigeration cycle. High heat density sources are directly mounted onto the cold plate. Temperature of the cold plate is regulated based on temperature feedback and is maintained above ambient temperatures. For LED applications, a number of LEDs are mounted onto the cold plate of the direct refrigeration cooling platform. Beams of light are distributed via fiber optic light guides to remote and inaccessible locations, where light sources are to be replaced. IC chips are cooled the same way with IC chips attached to the cold plate of the direct refrigeration cooling platform.

Abstract: Embodiments of a silicon-based heat dissipation device and a chip module assembly are described. An apparatus may include a silicon-based heat dissipation device, an extended device coupled to the silicon-based heat-dissipation device and heat-generating devices mounted on the silicon-based heat dissipation device. The silicon-based heat dissipation device may include a base portion having a first primary side and a second primary side opposite the first primary side. The silicon-based heat dissipation device may also include a protrusion portion on the first primary side of the base portion and protruding therefrom. The protrusion portion may include multiple fins. The base portion may include a slit opening with a first heat-generating device of the heat-generating devices on a first side of the slit opening and a second heat-generating device of the heat-generating devices on a second side of the slit opening opposite the first side of the slit opening.

Abstract: Various embodiments of a thermal energy transfer apparatus that removes thermal energy from a light-emitting device are described. In one aspect, an apparatus comprises a non-metal base plate and a silicon-based cover element disposed on the base plate. The base plate is coated with a first electrically-conductive pattern that forms a first electrode. The base plate is further coated with a second electrically-conductive pattern that is electrically isolated from the first electrically-conductive pattern. The cover element holds the one or more light-emitting devices between the base plate and the cover element with at least a portion of a light-emitting surface of each of the one or more light-emitting devices exposed. The cover element is coated with a third electrically-conductive pattern that is in contact with the second electrically-conductive pattern to form a second electrode when the cover element is disposed on the base plate.

Abstract: In one aspect, an apparatus comprises a substrate, a first electrically-driven device disposed on the substrate, a second electrically-driven device disposed on the substrate, and a composite heat sink device. The composite heat sink device comprises a first thermal conduction member, a second thermal conduction member, and a thermal insulation member. The first thermal conduction member is disposed on the first electrically-driven device such that at least a portion of the heat generated by the first electrically-driven device is transferred to the first thermal conduction member by conduction. The second thermal conduction member is disposed on the second electrically-driven device such that at least a portion of the heat generated by the second electrically-driven device is transferred to the second thermal conduction member by conduction. The thermal insulation member is disposed between and thermally decouples the first thermal conduction member and the second thermal conduction member from one another.

Abstract: In one aspect, an apparatus comprises a substrate, a first electrically-driven device disposed on the substrate, a second electrically-driven device disposed on the substrate, and a composite heat sink device. The composite heat sink device comprises a first thermal conduction member, a second thermal conduction member, and a thermal insulation member. The first thermal conduction member is disposed on the first electrically-driven device such that at least a portion of the heat generated by the first electrically-driven device is transferred to the first thermal conduction member by conduction. The second thermal conduction member is disposed on the second electrically-driven device such that at least a portion of the heat generated by the second electrically-driven device is transferred to the second thermal conduction member by conduction. The thermal insulation member is disposed between and thermally decouples the first thermal conduction member and the second thermal conduction member from one another.

Abstract: A thermal energy storage apparatus that absorbs thermal energy from a heat-generating device is described. In one aspect, the thermal energy storage apparatus comprises a non-metal container and a phase-change material. The non-metal container is configured to receive the heat-generating device thereon. The phase-change material is contained in the non-metal container and configured to absorb at least a portion of heat from the heat-generating device through the non-metal container.

Abstract: A thermal energy storage apparatus that absorbs thermal energy from a heat-generating device is described. In one aspect, the thermal energy storage apparatus comprises a non-metal container and a phase-change material. The non-metal container is configured to receive the heat-generating device thereon. The phase-change material is contained in the non-metal container and configured to absorb at least a portion of heat from the heat-generating device through the non-metal container.

Abstract: Embodiments of a mechanism of thermal isolation for multiple heat-generating devices on a substrate are described. In one aspect, a substrate is configured for a plurality of heat-generating devices to be disposed thereon. The substrate comprises an electrically-conductive layer that is electrically coupled to the heat-generating devices when the heat-generating devices are disposed on the substrate. The electrically-conductive layer is configured to thermally isolate the heat-generating devices such that there is no thermal coupling through the electrically-conductive layer amongst the heat-generating devices.

Abstract: Embodiments of a silicon-based heat dissipation device and a chip module assembly are described. An apparatus may include a silicon-based heat dissipation device, an extended device coupled to the silicon-based heat-dissipation device and heat-generating devices mounted on the silicon-based heat dissipation device. The silicon-based heat dissipation device may include a base portion having a first primary side and a second primary side opposite the first primary side. The silicon-based heat dissipation device may also include a protrusion portion on the first primary side of the base portion and protruding therefrom. The protrusion portion may include multiple fins. The base portion may include a slit opening with a first heat-generating device of the heat-generating devices on a first side of the slit opening and a second heat-generating device of the heat-generating devices on a second side of the slit opening opposite the first side of the slit opening.

Abstract: Embodiments of a silicon-based heat-dissipation device and an apparatus including a silicon-based heat-dissipation device are described. In one aspect, an apparatus includes a silicon-based heat-dissipation device which includes a base portion and a protrusion portion. The base portion has a first primary side and a second primary side opposite the first primary side. The protrusion portion is on the first primary side of the base portion and protruding therefrom. The protrusion portion includes multiple fins. Each of at least two immediately adjacent fins of the fins of the protrusion portion has a tapered profile in a cross-sectional view with a first width near a distal end of the respective fin being less than a second width at a base of the respective fin near the base portion of the heat-dissipation device.

Abstract: Embodiments of a silicon-based heat dissipation device and a chip module assembly utilizing the silicon-based heat dissipation device are described. In one aspect, the chip module assembly includes a chip module and a primary heat dissipation module. The chip module includes a board and at least one heat-generating device. The board includes a first primary side and a second primary side opposite the first primary side. The at least one heat-generating device is disposed on the first primary side of the board. The primary heat dissipation module includes at least one silicon-based heat dissipation device disposed on the at least one heat-generating device.

Abstract: Various embodiments of an apparatus that simultaneously cools and thermally decouples adjacent electrically-driven devices in close proximity are provided. In one aspect, an apparatus comprises a first non-silicon heat sink and a first silicon-based heat sink disposed on the first non-silicon heat sink. The first silicon-based heat sink is configured to receive a first electrically-driven device on a first portion of the first silicon-based heat sink and to receive a second electrically-driven device on a second portion of the first silicon-based heat sink. The first silicon-based heat sink includes a first groove or a first opening between the first portion and the second portion such that a heat conduction path between the first electrically-driven device and the first non-silicon heat sink through the first silicon-based heat sink is shorter than a heat conduction path between the first electrically-driven device and the second electrically-driven device through the first silicon-based heat sink.

Abstract: Embodiments of a silicon-based heat-dissipation device and an apparatus including a silicon-based heat-dissipation device are described. In one aspect, an apparatus includes a silicon-based heat-dissipation device which includes a base portion and a protrusion portion. The base portion has a first primary side and a second primary side opposite the first primary side. The protrusion portion is on the first primary side of the base portion and protruding therefrom. The protrusion portion includes multiple fins. Each of at least two immediately adjacent fins of the fins of the protrusion portion has a tapered profile in a cross-sectional view with a first width near a distal end of the respective fin being less than a second width at a base of the respective fin near the base portion of the heat-dissipation device.

Abstract: Various embodiments of an apparatus that simultaneously cools and thermally decouples adjacent electrically-driven devices in close proximity are provided. In one aspect, an apparatus comprises a first non-silicon heat sink and a first silicon-based heat sink disposed on the first non-silicon heat sink. The first silicon-based heat sink is configured to receive a first electrically-driven device on a first portion of the first silicon-based heat sink and to receive a second electrically-driven device on a second portion of the first silicon-based heat sink. The first silicon-based heat sink includes a first groove or a first opening between the first portion and the second portion such that a heat conduction path between the first electrically-driven device and the first non-silicon heat sink through the first silicon-based heat sink is shorter than a heat conduction path between the first electrically-driven device and the second electrically-driven device through the first silicon-based heat sink.