An input/output (I/O) circuit includes at least one I/O cell having a first size, and a high current circuit coupled to the at least one I/O cell. The high current circuit has a second size that is smaller than the first size. A connection bus is coupled to the high current circuit. The connection bus has the second size and is positioned in substantially a same location within the I/O circuit as the high current circuit. A bump or a bond pad is coupled to the connection bus.

A semiconductor device includes a substrate including a substrate top surface; interconnects connected to the substrate and extending above the substrate top surface; a die attached over the substrate, wherein the die includes a die bottom surface that connects to the interconnects for electrically coupling the die and the substrate; and a metal enclosure directly contacting and vertically extending between the substrate top surface and the die bottom surface, wherein the metal enclosure peripherally surrounds the interconnects.

Embodiments relate to the design of a device capable of increasing the electrical performance of an interconnect feature by amplifying the current carrying capacity of an interconnect feature. The device comprises a first body comprising a first surface with at least one nanoporous conductive structure protruding from the first surface. The device further comprises a second body comprising a second surface with arrays of nanofibers extending from the second surface and penetrating into corresponding nanoporous conductive structures to form conductive pathways between the first body and the second body.

A photodetector-array and fabrication method thereof are disclosed. The photodetector-array includes a first and second semiconductor structures having respective active regions defining respective pluralities of active photodetectors and active readout integrated circuit pixels (RICPs) electronically connectable to one another respectively. The first and second semiconductor structures are made with different semiconductor materials/compositions having different first and second coefficients of thermal expansion (CTEs) respectively. The pitch distances of the active photodetectors and the pitch distances of the respective active RICPs are configured in accordance with the difference between the first and second CTEs, such that at high temperatures, at which electrical coupling between the first and second semiconductor structures is performed, the electric contacts of the active photodetectors and of their respective RICPs overlap. Accordingly, after the first and second semiconductor structures are bonded together, at least 99.5% of the active photodetector are electrically connected with their respective RICPs.

A semiconductor device includes a substrate including a substrate top surface; interconnects connected to the substrate and extending above the substrate top surface; a die attached over the substrate, wherein the die includes a die bottom surface that connects to the interconnects for electrically coupling the die and the substrate; and a metal enclosure directly contacting and vertically extending between the substrate top surface and the die bottom surface, wherein the metal enclosure peripherally surrounds the interconnects.

Provided is a multilayer substrate including laminated semiconductor substrates each having a penetrating hole (hereinafter referred to as through hole) having a plated film formed in the inner surface. The multilayer substrate has excellent conduction characteristics and can be manufactured at low cost. Conductive particles are selectively present at a position where the through holes face each other as viewed in a plan view of the multilayer substrate. The multilayer substrate has a connection structure in which the facing through holes are connected by the conductive particles, and the semiconductor substrates each having the through hole are bonded by an insulating adhesive.

Provided is a multilayer substrate including laminated semiconductor substrates each having a penetrating hole (hereinafter referred to as through hole) having a plated film formed in the inner surface. The multilayer substrate has excellent conduction characteristics and can be manufactured at low cost. Conductive particles are selectively present at a position where the through holes face each other as viewed in a plan view of the multilayer substrate. The multilayer substrate has a connection structure in which the facing through holes are connected by the conductive particles, and the semiconductor substrates each having the through hole are bonded by an insulating adhesive.

A semiconductor device includes a substrate including a substrate top surface; interconnects connected to the substrate and extending above the substrate top surface; a die attached over the substrate, wherein the die includes a die bottom surface that connects to the interconnects for electrically coupling the die and the substrate; and a metal enclosure directly contacting and vertically extending between the substrate top surface and the die bottom surface, wherein the metal enclosure peripherally surrounds the interconnects.

Provided is a multilayer substrate obtained by laminating semiconductor substrates each having a trough electrode. The multilayer substrate has excellent conduction characteristics and can be manufactured at low cost. Conductive particles are each selectively present at a position where the through electrodes face each other as viewed in a plan view of the multilayer substrate. The multilayer substrate has a connection structure in which the facing through electrodes are connected by the conductive particles, and the semiconductor substrates each having the through electrode are bonded by an insulating adhesive.

Provided is a multilayer substrate obtained by laminating semiconductor substrates each having a trough electrode. The multilayer substrate has excellent conduction characteristics and can be manufactured at low cost. Conductive particles are each selectively present at a position where the through electrodes face each other as viewed in a plan view of the multilayer substrate. The multilayer substrate has a connection structure in which the facing through electrodes are connected by the conductive particles, and the semiconductor substrates each having the through electrode are bonded by an insulating adhesive.