A connection body which comprises a base structure at least predominantly made of a semiconductor oxide material or glass material, and an electrically conductive wiring structure on and/or in the base structure, wherein the electrically conductive wiring structure comprises at least one vertical wiring section with a first lateral dimension on and/or in the base structure and at least one lateral wiring section connected with the at least one vertical wiring section, wherein the at least one lateral wiring section has a second lateral dimension on and/or in the base structure, which is different to the first lateral dimension.

In one embodiment, a semiconductor device includes a substrate, a lower pad provided above the substrate, and an upper pad provided on the lower pad. The lower pad includes a first pad and a plurality of first connection portions provided on the first pad, and the upper pad is provided on the plurality of first connection portions, or the upper pad includes a second pad and a plurality of second connection portions provided under the second pad, and the lower pad is provided under the plurality of second connection portions.

A method includes bonding a first and a second device die to a third device die, forming a plurality of gap-filling layers extending between the first and the second device dies, and performing a first etching process to etch a first dielectric layer in the plurality of gap-filling layers to form an opening. A first etch stop layer in the plurality of gap-filling layers is used to stop the first etching process. The opening is then extended through the first etch stop layer. A second etching process is performed to extend the opening through a second dielectric layer underlying the first etch stop layer. The second etching process stops on a second etch stop layer in the plurality of gap-filling layers. The method further includes extending the opening through the second etch stop layer, and filling the opening with a conductive material to form a through-via.

A hybrid bonded structure including a first integrated circuit component and a second integrated circuit component is provided. The first integrated circuit component includes a first dielectric layer, first conductors and isolation structures. The first conductors and the isolation structures are embedded in the first dielectric layer. The isolation structures are electrically insulated from the first conductors and surround the first conductors. The second integrated circuit component includes a second dielectric layer and second conductors. The second conductors are embedded in the second dielectric layer. The first dielectric layer is bonded to the second dielectric layer and the first conductors are bonded to the second conductors.

A method of manufacturing a power module comprising two substrates is provided, wherein the method comprises disposing a compensation layer of a first thickness above a first substrate; disposing a second substrate above the compensation layer; and reducing the thickness of the compensation layer from the first thickness to a second thickness after the second substrate is disposed on the compensation layer.

A method for transferring a plurality of die operatively associated with a transfer apparatus to a glass substrate to form a circuit component. The transfer occurs by positioning the glass substrate to face a first surface of a die carrier carrying multiple die. A reciprocating transfer member thrusts against a second surface of the die carrier to actuate the transfer member thereby causing a localized deflection of the die carrier in a direction of the surface of the glass substrate to position an initial die proximate to the glass substrate. The initial die transfers directly to a circuit trace on the glass substrate. At least one of the die carrier or the transfer member is then shifted such that the transfer member aligns with a subsequent die on the first surface of the die carrier. The acts of actuating, transferring, and shifting are repeated to effectuate a transfer of the multiple die onto the glass substrate.

Embodiments of through array contact structures of a 3D memory device and fabricating method thereof are disclosed. The memory device includes an alternating layer stack disposed on a first substrate. The alternating layer stack includes a first region including an alternating dielectric stack, and a second region including an alternating conductor/dielectric stack. The memory device further comprises a barrier structure including two parallel barrier walls extending vertically through the alternating layer stack and laterally along a word line direction to laterally separate the first region from the second region. The memory device further comprises a plurality of through array contacts in the first region, each through array contact extending vertically through the alternating dielectric stack.

The subject application discloses a substrate. The substrate includes a first conductive layer, a first bonding layer, a first dielectric layer, and a conductive via. The first bonding layer is disposed on the first conductive layer. The first dielectric layer is disposed on the first bonding layer. The conductive via penetrates the first dielectric layer and is electrically connected with the first conductive layer.

An interconnect structure includes a plurality of first pads arranged to form a first array and a plurality of second pads arranged to form a second array. Each of the first array has a first row, a second row and an m.sup.th row extending along a first direction and parallel to each other along a second direction. The first pads in each of the first row, the second row and the m.sup.th row are grouped into a first group, a second group and an n.sup.th group extending along the second direction. The second pads in each of the first row, the second row and the m.sup.th row are grouped into a first group, a second group and an n.sup.th group extending along the second direction. The interconnect structure further includes a plurality of first conductive lines, a plurality of second conductive lines and a plurality of n.sup.th conductive lines.

A nano-twinned structure on a metallic thin film surface is provided. The nano-twinned structure includes a substrate, an adhesive-lattice-buffer layer over the substrate, and a metallic thin film including Ag, Cu, Au, Pd or Ni over the adhesive-lattice-buffer layer. The bottom region of the metallic thin film has equi-axial coarse grains. The surface region of the metallic thin film contains parallel-arranged high-density twin boundaries (Σ3+Σ9) with a pitch from 1 nm to 100 nm. The quantity of the parallel-arranged twin boundaries is 50% to 80% of the total quantity of twin boundaries in the cross-sectional view of the metallic thin film. The parallel-arranged twin boundaries include 30% to 90% [111] crystal orientation. The nano-twinned structure on the metallic thin film surface is formed through a post-deposition ion bombardment on the evaporated metallic thin film surface after the evaporation process.