A method for fabricating a three-dimensional (3D) stacked integrated circuit. Pick-and-place strategies are used to stack the source wafers with device layers fabricated using standard two-dimensional (2D) semiconductor fabrication technologies. The source wafers may be stacked in either a sequential or parallel fashion. The stacking may be in a face-to-face, face-to-back, back-to-face or back-to-back fashion. The source wafers that are stacked in a face-to-back, back-to-face or back-to-back fashion may be connected using Through Silicon Vias (TSVs). Alternatively, source wafers that are stacked in a face-to-face fashion may be connected using Inter Layer Vias (ILVs).

A semiconductor device and a method of manufacturing the semiconductor device are disclosed. The semiconductor device includes a substrate, a first through substrate via configured to penetrate at least partially through the substrate, the first through substrate via having a first aspect ratio, and a second through substrate via configured to penetrate at least partially through the substrate. The second through substrate via has a second aspect ratio greater than the first aspect ratio, and each of the first through substrate via and the second through substrate via includes a first conductive layer and a second conductive layer. A thickness in a vertical direction of the first conductive layer of the first through substrate via is less than a thickness in the vertical direction of the first conductive layer of the second through substrate via.

According to some example embodiments of the inventive concepts, there is provided a method of operating a stacked memory device including a plurality of memory dies stacked in a vertical direction, the method including receiving a command and an address from a memory controller, determining a stack ID indicating a subset of the plurality of memory dies by decoding the address, and accessing at least two memory dies among the subset of memory dies corresponding to the stack ID such that the at least two memory dies are non-adjacent.

A semiconductor package comprising a first semiconductor chip and a second semiconductor chip disposed on the first semiconductor chip, wherein the first semiconductor chip includes a first semiconductor body, an upper pad structure, and a first through-electrode penetrating the first semiconductor body and electrically connected to the upper pad structure, and the second semiconductor chip includes a second semiconductor body, a lower bonding pad, and an internal circuit structure including a circuit element, internal circuit wirings, and a connection pad pattern disposed on the same level as the lower bonding pad, the upper pad structure includes upper bonding pads and connection wirings, the upper bonding pads are disposed at positions corresponding to the lower bonding pad and the connection pad pattern, and the internal circuit structure is electrically connected to the first through-electrode through at least one of the upper bonding pads and the connection wirings.

A device including a stack of dies. Each of the dies can have unit stair-step conductive paths of connection features which include through-die via structures and routing structures. The unit stair-step conductive paths of one of the dies can be interconnected to another one of the unit stair-step conductive paths of another one of the dies to form one of a plurality conductive stair-case structures through two or more of the dies. The unit stair-step conductive paths can be connected to reduce signal cross talk between the conductive stair-case structures whereby at least some of the conductive stair-case structures are connected to transmit a same polarity of electrical signals are spatially separated in a dimension that is perpendicular to a major surface of the dies. A method of manufacturing the device is also disclosed.

A 3D device including: a first level including first transistors and a first interconnect; a second level including second transistors, the second level overlaying the first level; and at least eight electronic circuit units (ECUs), where each of the at least eight ECUs includes a first circuit, the first circuit including a portion of the first transistors, where each of the at least eight ECUs includes a second circuit, the second circuit including a portion of the second transistors, where each of the at least eight ECUs includes a first vertical bus, where the first vertical bus includes greater than eight pillars and less than three hundred pillars, where the first vertical bus provides electrical connections between the first circuit and the second circuit, where the second level is bonded to the first level, and where the bonded includes oxide to oxide bonding regions and metal to metal bonding regions.

Various embodiments of the present technology provide for the ultra-high density heterogenous integration, enabled by nano-precise pick-and-place assembly. For example, some embodiments provide for the integration of modular assembly techniques with the use of prefabricated blocks (PFBs). These PFBs can be created on one or more sources wafers. Then using pick-and-place technologies, the PFBs can be selectively arranged on a destination wafer thereby allowing Nanoscale-aligned 3D Stacked Integrated Circuit (N3-SI) and the Microscale Modular Assembled ASIC (M2A2) to be efficiently created. Some embodiments include systems and techniques for the construction of construct semiconductor devices which are arbitrarily larger than the standard photolithography field size of 26×33 mm, using pick-and-place assembly.

A semiconductor package may include a redistribution substrate, a first semiconductor chip on the redistribution substrate, and a second semiconductor chip between the redistribution substrate and the first semiconductor chip. The second semiconductor chip may have a width in a first direction that is smaller than a width of the first semiconductor chip in the first direction. The first semiconductor chip may include a first alignment key pattern on a bottom surface thereof. The second semiconductor chip may be spaced apart from the first alignment key pattern. The second semiconductor chip may include a second interconnection layer on the bottom surface of the first semiconductor chip, a second semiconductor substrate on a bottom surface of the second interconnection layer and exposing a bottom surface of an edge region of the second interconnection layer, and a second alignment key pattern on the edge region of the second interconnection layer.

Bonded structures having conductive features and isolation features are disclosed. In one example, a bonded structure can include a first element including a first insulating layer and at least two first conductive features disposed in the first insulating layer. The bonded structure can also include a second element including a second insulating layer and at least two second conductive features disposed in the second insulating substrate. The first element can be directly bonded to the second element with the at least two first conductive features aligned with the at least two second conductive features. The bonded structure can also include an isolation feature in the second insulating layer and between the at least two second conductive features. The isolation feature can have a dielectric constant lower than a dielectric constant of the second insulating layer.

Microelectronic devices having stacked electromagnetic coils are disclosed. In one example, a microelectronic device can include a first semiconductor element and a second semiconductor element disposed on the first semiconductor element. The microelectronic device can also include an electromagnetic coil. A first portion of the electromagnetic coil and a second portion of the electromagnetic coil may be spaced apart by the first semiconductor element. A first conductive via extending through the first semiconductor element may connect the first and second portions of the electromagnetic coil. Methods for forming such microelectronic devices are also disclosed.