A method for manufacturing a semiconductor device includes forming a trench in at least one dielectric layer; and forming an interconnect structure in the trench, wherein forming the interconnect structure includes forming a first conductive layer on a bottom surface of the trench, and partially filling the trench, and forming a second conductive layer on the first conductive layer, and filling a remaining portion of the trench, wherein the second conductive layer comprises a different material from the first conductive layer, and wherein an amount of the first conductive layer in the trench is controlled so that an aspect ratio of the second conductive layer has a value that is determined to result in columnar grain boundaries in the second conductive layer.

A three-dimensional stacking structure is described. The stacking structure includes at least a bottom die, a top die and a spacer protective structure. The bottom die includes contact pads in the non-bonding region. The top die is stacked on the bottom die without covering the contact pads of the bottom die and the bottom die is bonded with the top die through bonding structures there-between. The spacer protective structure is disposed on the bottom die and covers the top die to protect the top die. By forming an anti-bonding layer before stacking the top dies to the bottom dies, the top die can be partially removed to expose the contact pads of the bottom die for further connection.

A fabricating method of a semiconductor device is provided. A temporary semiconductor structure is provided. The temporary semiconductor structure includes a temporary substrate and a conductive layer, the temporary substrate has a first surface, the conductive layer is disposed on the first surface of the temporary substrate, and the conductive layer includes one or more first trace. Then, a recess is formed in the temporary semiconductor structure to form a first semiconductor structure and a first substrate. The recess penetrates through the first substrate and expose the one or more first trace. Thereafter, an input/output pad is formed in the recess and on the one or more first trace.

A semiconductor device may include a first pattern. The semiconductor device may include a second pattern intersecting with the first pattern and including an intersection region with the first pattern and a non-intersection region.

A vertical memory device includes a substrate including a cell region and a peripheral circuit region, gate electrodes sequentially stacked on the cell region of the substrate in a vertical direction substantially perpendicular to an upper surface of the substrate, a channel on the cell region and extending through the gate electrodes in the vertical direction, a first lower contact plug on the peripheral circuit region and extending in the vertical direction, a second lower contact plug on the peripheral circuit region adjacent to the first lower contact plug and extending in the vertical direction, and a first upper wiring electrically connected to the first lower contact plug. The first upper wiring is configured to and apply an electrical signal to the first lower contact plug. The second lower contact plug is not electrically connected to an upper wiring configured to apply an electrical signal.

A semiconductor device and a method for forming a semiconductor are provided. The semiconductor device includes: a first substrate, a first conductive line disposed on the first substrate, a second substrate opposite to the first substrate, a second conductive line disposed on the second substrate and adjacent to the first conductive line, and a plurality of bonding structures between the first conductive line and the second conductive line. The first conductive line includes a plurality of first segments separated from one another. The second conductive line includes a plurality of second segments separated from one another. Each of the bonding structures is connected to a respective first segment of the plurality of first segments and a respective second segment of the plurality of second segments such that the plurality of first segments, the plurality of bonding structures and the plurality of second segments are connected in series.

Microelectronic devices include a stack structure of insulative structures vertically alternating with conductive structures and arranged in tiers forming opposing staircase structures. A polysilicon fill material substantially fills an opening (e.g., a high-aspect-ratio opening) between the opposing staircase structures. The polysilicon fill material may have non-compressive stress such that the stack structure may be partitioned into blocks without the blocks bending and without contacts—formed in at least one of the polysilicon fill material and the stack structure—deforming, misaligning, or forming electrical shorts with neighboring contacts.

A semiconductor structure (MG) includes a metal gate structure disposed over a semiconductor substrate, a dielectric layer disposed adjacent to the MG, a source/drain (S/D) feature disposed adjacent to the dielectric layer, and a S/D contact disposed over the S/D feature. The S/D contact includes a first metal layer disposed over the S/D feature and a second metal layer disposed on the first metal layer.

A three-dimensional semiconductor memory device including a first peripheral circuit including different decoder circuits, a first memory on the first peripheral circuit, the first memory including a first stack structure having first electrode layers stacked on one another and first inter-electrode dielectric layers therebetween, a first planarized dielectric layer covering an end of the first stack structure, and a through via that penetrates the end of the first stack structure, the through via electrically connected to one of the decoder circuits, and a second memory on the first memory and including a second stack structure having second electrode layers stacked on one another and second inter-electrode dielectric layers therebetween, a second planarized dielectric layer covering an end of the second stack structure, and a cell contact plug electrically connecting one of the second electrode layers to the through via.

A metallic stack and a preparing method therefor, and an electronic device including the metallic stack. The metallic stack includes at least one interconnection wire layer and at least one via layer alternately arranged on a substrate. At least one pair of interconnection wire layer and via layer in the metallic stack includes interconnection wires in the interconnection wire layer and conductive vias in the via layer, wherein the interconnection wire layer is closer to the substrate than the via layer. At least a part of the interconnection wires is integrated with the conductive vias on the at least a part of the interconnection wires.