This application is directed to a semiconductor system including a substrate, an electronic device, a plurality of compliant interconnects and a support structure. The substrate has a first surface and a plurality of first contacts formed on the first surface. The electronic device has a second surface facing the first surface of the substrate, and a plurality of second contacts formed on the second surface. The compliant interconnects are disposed between the first surface of the substrate and the second surface of the electronic device, and are configured to electrically couple the first contacts on the first surface of the substrate to the second contacts on the second surface of the electronic device. The support structure is coupled to the substrate and the electronic device, and extends beyond a footprint of the electronic device. The support structure is configured to mechanically couple the electronic device to the substrate.

This application is directed to a semiconductor system including a substrate, an electronic device, a plurality of compliant interconnects and a support structure. The substrate has a first surface and a plurality of first contacts formed on the first surface. The electronic device has a second surface facing the first surface of the substrate, and a plurality of second contacts formed on the second surface. The compliant interconnects are disposed between the first surface of the substrate and the second surface of the electronic device, and are configured to electrically couple the first contacts on the first surface of the substrate to the second contacts on the second surface of the electronic device. The support structure is coupled to the substrate and the electronic device, and extends beyond a footprint of the electronic device. The support structure is configured to mechanically couple the electronic device to the substrate.

A stamp for micro-transfer printing includes a support having a support stiffness and a support coefficient of thermal expansion (CTE). A pedestal layer is formed on the support, the pedestal layer having a pedestal layer stiffness that is less than the support stiffness and a pedestal layer coefficient of thermal expansion (CTE) that is different from the support coefficient of thermal expansion (CTE). A stamp layer is formed on the pedestal layer, the stamp layer having a body and one or more protrusions extending from the body in a direction away from the pedestal layer. The stamp layer has a stamp layer stiffness that is less than the support stiffness and a stamp layer coefficient of thermal expansion that is different from the support coefficient of thermal expansion.

A mounting structure includes a first substrate that has a first surface on which a functional element is provided, a wiring that is provided at a position which is different from a position of the functional element on the first surface, and is connected to the functional element, a second substrate that has a second surface facing the first surface, and a conductor that is provided on the second surface, and is connected to the wiring and the functional element, in which the shortest distance between the functional element and the second substrate is longer than a distance between a position where the wiring is connected to the conductor, and the second substrate.

A variable-stiffness module comprises a rigid structure (10) having a first stiffness, an intermediate substrate (20) having a second stiffness less than the first stiffness, and a flexible substrate (30) having a third stiffness less than the second stiffness. The rigid structure (10) is disposed on the intermediate substrate (20) and the intermediate substrate (20) is disposed on the flexible substrate (30). A conductor (40) is disposed partially on the intermediate substrate (21) and partially on the flexible substrate (30) and connected to the rigid structure (10). The conductor (40) extends from the rigid structure (10) to the intermediate substrate (21) to the flexible substrate (30). In some embodiments, a variable-stiffness module comprises any combination of multiple rigid structures, multiple intermediate substrates, and multiple conductors. The conductor (40) can be an optical conductor or an electrical conductor and can be disposed over the rigid structure (10) or between the rigid structure (10) and the intermediate substrate (21).

A device comprises a first sealing member, a second sealing member, a first circuit member and a second circuit member. The first sealing member comprises, as a base thereof, a first film formed of a film and comprises a conductive portion made of conductor. The device is formed with a closed space. The closed space is enclosed by the first sealing member and the second sealing member and is shut off from an outer space located outside the device. The first circuit member and the second circuit member are shut in the closed space and comprise a first contact point and a second contact point, respectively. At least one of the first circuit member and the second circuit member comprises an electrode. The conductive portion is in contact with the electrode in the closed space and is partially exposed to the outer space located outside the device.

A device comprises a first sealing member, a second sealing member, a first circuit member and a second circuit member. The first sealing member comprises, as a base thereof, a first film formed of a film and comprises a conductive portion made of conductor. The device is formed with a closed space. The closed space is enclosed by the first sealing member and the second sealing member and is shut off from an outer space located outside the device. The first circuit member and the second circuit member are shut in the closed space and comprise a first contact point and a second contact point, respectively. At least one of the first circuit member and the second circuit member comprises an electrode. The conductive portion is in contact with the electrode in the closed space and is partially exposed to the outer space located outside the device.

A stamp for micro-transfer printing includes a support having a support stiffness and a support coefficient of thermal expansion (CTE). A pedestal layer is formed on the support, the pedestal layer having a pedestal layer stiffness that is less than the support stiffness and a pedestal layer coefficient of thermal expansion (CTE) that is different from the support coefficient of thermal expansion (CTE). A stamp layer is formed on the pedestal layer, the stamp layer having a body and one or more protrusions extending from the body in a direction away from the pedestal layer. The stamp layer has a stamp layer stiffness that is less than the support stiffness and a stamp layer coefficient of thermal expansion that is different from the support coefficient of thermal expansion.

A device for cooling a plurality of electrical components, each having a component cooling surface to be cooled, includes a first heat sink, a second heat sink, and a plurality of fasteners. The first heat sink has a first heat-sink cooling surface, and the second heat sink has a second heat-sink cooling surface. The first and second heat-sink cooling surfaces are positioned in a planar arrangement such that the first and second heat-sink cooling surfaces face each other. The first heat-sink cooling surface is configured to receive a first sub-set of the component cooling surfaces of the plurality of electrical components, and the second heat-sink cooling surface is configured to receive a second sub-set of the component cooling surfaces. The fasteners are configured to fasten the first and second heat-sink cooling surfaces to the corresponding component cooling surfaces of the plurality of electrical components to be applied.

An example of a printed structure comprises a target substrate and a structure protruding from a surface of the target substrate. A component comprising a component substrate separate and independent from the target substrate is disposed in alignment with the structure on the surface of the target substrate within 1 micron of the structure. An example method of making a printed structure comprises providing the target substrate with the structure protruding from the target substrate, a transfer element, and a component adhered to the transfer element. The component comprises a component substrate separate and independent from the target substrate. The transfer element and adhered component move vertically toward the surface of the target substrate and horizontally towards the structure until the component physically contacts the structure or is adhered to the surface of the target substrate. The transfer element is separated from the component.