A controller according to an exemplary aspect of the present disclosure includes, among other things, a cold plate and at least one electronic component mounted to the cold plate by an intermediate thermoelectric cooler.

Three-dimensional integrated circuit structures providing thermoelectric cooling and methods for cooling such integrated circuit structures are disclosed. In one exemplary embodiment, a three-dimensional integrated circuit structure includes a plurality of integrated circuit chips stacked one on top of another to form a three-dimensional chip stack, a thermoelectric cooling daisy chain comprising a plurality of vias electrically connected in series with one another formed surrounding the three-dimensional chip stack, a thermoelectric cooling plate electrically connected in series with the thermoelectric cooling daisy chain, and a heat sink physically connected with the thermoelectric cooling plate.

Three-dimensional integrated circuit structures providing thermoelectric cooling and methods for cooling such integrated circuit structures are disclosed. In one exemplary embodiment, a three-dimensional integrated circuit structure includes a plurality of integrated circuit chips stacked one on top of another to form a three-dimensional chip stack, a thermoelectric cooling daisy chain comprising a plurality of vias electrically connected in series with one another formed surrounding the three-dimensional chip stack, a thermoelectric cooling plate electrically connected in series with the thermoelectric cooling daisy chain, and a heat sink physically connected with the thermoelectric cooling plate.

A microelectronic device including a substrate having a semiconductor material containing an embedded thermoelectric cooler with thermally anisotropic mesas between the cold terminal and the hot terminal of the embedded thermoelectric cooler adjacent to a heat source; the adjacent embedded thermoelectric cooler providing a temperature reduction for the heat source resulting in increased safe operating area (SOA) for the microelectronic device. The thermally anisotropic mesas are formed in parallel with deep trenches used as isolation in the microelectronic device.

A photodetector comprising a photoabsorber, comprising a doped semiconductor, a contact layer comprising a doped semiconductor and a barrier layer comprising a charge carrier compensated semiconductor, the barrier layer compensated by doping impurities such that it exhibits a valence band energy level substantially equal to the valence band energy level of the photo absorbing layer and a conduction band energy level exhibiting a significant band gap in relation to the conduction band of the photo absorbing layer, the barrier layer disposed between the photoabsorber and contact layers. The relationship between the photo absorbing layer and contact layer valence and conduction band energies and the barrier layer conduction and valance band energies is selected to facilitate minority carrier current flow while inhibiting majority carrier current flow between the contact and photo absorbing layers.

In some aspects, the disclosed technology provides microelectronic devices which can effectively dissipate heat and methods of forming the disclosed microelectronic devices. In some embodiments, a disclosed device may include a first integrated device die. The disclosed device may further include a thermoelectric element bonded to the first integrated device die. The disclosed device may further include a heat sink disposed over at least the thermoelectric element. The thermoelectric element may be configured to transfer heat from the first integrated device die to the heat sink. The thermoelectric element directly may be bonded to the first integrated device die without an adhesive.

In some aspects, the disclosed technology provides microelectronic devices which can effectively dissipate heat and methods of forming the disclosed microelectronic devices. In some embodiments, a disclosed device may include a first integrated device die. The disclosed device may further include a thermoelectric element bonded to the first integrated device die. The disclosed device may further include a heat sink disposed over at least the thermoelectric element. The thermoelectric element may be configured to transfer heat from the first integrated device die to the heat sink. The thermoelectric element directly may be bonded to the first integrated device die without an adhesive.

In some aspects, the disclosed technology provides microelectronic devices which can effectively dissipate heat and manage hot spot. In some embodiments, a disclosed microelectronic device may include a substrate having a thickness in a first direction and at least one thermoelectric unit disposed in or on the substrate. The thermoelectric unit may be configured to transfer heat along a second lateral direction orthogonal to the first direction.

In some aspects, the disclosed technology provides microelectronic devices which can effectively dissipate heat and manage hot spot. In some embodiments, a disclosed microelectronic device may include a substrate having a thickness in a first direction and at least one thermoelectric unit disposed in or on the substrate. The thermoelectric unit may be configured to transfer heat along a second lateral direction orthogonal to the first direction.

A cooling system comprises a board management controller (BMC), a thermoelectric cooling (TEC) controller, and a cooling distribution unit (CDU) controller. The BMC monitors a cooling system to obtain a first power value representing a power consumed by an electronic device, performs a lookup operation in a control lookup table based on the first power value, and determines a first thermoelectric cooling (TEC) current and a first pump speed based on the lookup operation. The TEC controller is to control a TEC device attached to the electronic device to cause the first TEC current to flow within the TEC device. The CDU controller is to configure a pump speed of a fluid pump of the CDU according to the first pump speed.