An integrated circuit structure includes a first metallization layer with first and second electrodes, each of which has electrode fingers. A second metallization layer may be included below the first metallization layer and include one or more electrodes with electrode fingers. The integrated circuit structure is configured to exhibit at least partial vertical inductance cancellation when the first electrode and second electrode are energized. The integrated circuit structure can be configured to also exhibit horizontal inductance cancellation between adjacent electrode fingers. Also disclosed is a simulation model that includes a capacitor model that models capacitance between electrode fingers having a finger length and includes at least one resistor-capacitor series circuit in which a resistance of the resistor increases with decreasing finger length for at least some values of the finger length.

The semiconductor structure includes a first capacitive structure located on a substrate and first support columns. A plurality of first support columns are disposed on the substrate in parallel and spaced apart from each other, and are located in a same plane parallel to the substrate. The first capacitive structure includes a first lower electrode layer, a first dielectric layer and a first upper electrode layer. The semiconductor structure further includes a plurality of first segmentation trenches. The first segmentation trenches divide the first capacitive structure into a plurality of capacitors. A first insulation layer is disposed between the corresponding first lower electrode layers of the adjacent capacitors. The corresponding first upper electrode layers of the adjacent capacitors are electrically connected to each other.

The present disclosure provides a manufacturing method of a semiconductor structure, and a semiconductor structure. The manufacturing method of a semiconductor structure includes: forming a plurality of cylindrical capacitors in an initial structure; removing part of the initial structure to form trenches, the trenches expose partial sidewalls of the cylindrical capacitors and a substrate of the initial structure; forming a dielectric layer, the dielectric layer at least covers an exposed surface of each of the cylindrical capacitors; forming a first top electrode, the first top electrode covers a surface of the dielectric layer; and forming a second top electrode, the second top electrode covers a surface of the first top electrode. In an axial direction of each of the cylindrical capacitors, the second top electrode formed in each of the trenches has a discontinuous part, and an air gap is formed in the discontinuous part of the second top electrode.

Disclosed herein are memory cells and memory arrays, as well as related methods and devices. For example, in some embodiments, a memory device may include: a support having a surface; and a three-dimensional array of memory cells on the surface of the support, wherein individual memory cells include a transistor and a capacitor, and a channel of the transistor in an individual memory cell is oriented parallel to the surface.

The present application discloses a semiconductor device and a method for fabricating the semiconductor device. The semiconductor device includes a first palm portion positioned above a substrate; a second palm portion positioned above the substrate and opposite to the first palm portion; a first finger portion arranged substantially in parallel with a main surface of the substrate, positioned between the first palm portion and the second palm portion, and connecting to the first palm portion; a second finger portion arranged substantially in parallel with the first finger portion, positioned between the first palm portion and the second palm portion, and connecting to the second palm portion; a capacitor insulation layer positioned between the first finger portion and the second finger portion; a first spacer positioned between the first palm portion and second finger portion; and a second spacer positioned between the second palm portion and the first finger portion.

A semiconductor memory device and method for making the same. The semiconductor device includes a transistor laterally extending in a direction parallel to a substrate and including an active layer over the substrate, the active layer having a first end and a second end; bit line contact nodes formed on an upper surface and a lower surface of the first end of the active layer, respectively; a bit line side-ohmic contact vertically extending and connecting to the first end of the active layer and the bit line contact nodes; a bit line extending in a vertical direction to the substrate and connected to the bit line side-ohmic contact; and a capacitor connected to the second end of the active layer.

A microelectronic device comprises a first microelectronic device structure and a second microelectronic device structure attached to the first microelectronic device structure. The first microelectronic device structure comprises a memory array region comprising a stack structure comprising levels of conductive structures vertically alternating with levels of insulative structures, and staircase structures at lateral ends of the stack structure. The memory array region further comprises vertical stacks of memory cells, at least one of the vertical stacks of memory cells comprising stacked capacitor structures, each stacked capacitor structure comprising capacitor structures vertically spaced from each other by at least a level of the levels of insulative structures, transistor structures, each transistor structure operably coupled to a capacitor structure and to one of the conductive structures of the levels of conductive structures, and a conductive pillar structure vertically extending through the transistor structures. The first microelectronic device further comprises conductive contact structures in electrical communication with the levels of conductive structures at steps of the staircase structures. The second microelectronic device comprises control logic devices configured to effectuate at least a portion of control operations for the vertical stacks of memory cells, conductive interconnect structures vertically extending through an oxide material and in electrical communication with the conductive contact structures, and an additional conductive interconnect structure vertically extending through the oxide material and in electrical communication with the conductive pillar structure of the at least one of the vertical stacks of memory cells. Related microelectronic devices, electronic systems, and methods are also described.

A semiconductor device includes: a substrate; a first dielectric layer over the substrate; a memory cell over the substrate in a first region of the semiconductor device, where the memory cell includes a first ferroelectric structure in the first dielectric layer, where the first ferroelectric structure includes a first bottom electrode, a first top electrode, and a first ferroelectric layer in between; and a tunable capacitor over the substrate in a second region of the semiconductor device, where the tunable capacitor includes a second ferroelectric structure, where the second ferroelectric structure includes a second bottom electrode, a second top electrode, and a second ferroelectric layer in between, where at least a portion of the second ferroelectric structure is in the first dielectric layer.

A device may include a substrate, and an interlevel dielectric arranged over the substrate. The interlevel dielectric may include a first interlevel dielectric layer in an interconnect level i, the first interlevel dielectric layer having a first interconnect and a second interconnect therein. A nitride block insulator may be arranged over the first interlevel dielectric layer and over the first interconnect and the second interconnect. An opening may be arranged in the nitride block insulator, the opening extending through the nitride block insulator to expose a surface of the first interconnect in the first interlevel dielectric layer. A contact plug may be arranged in the opening of the nitride block insulator. The contact plug at least lines the opening and prevents out-diffusion of conductive material from the first interconnect. A thin film of a passive component may be arranged over the nitride block insulator and over the contact plug.

Disclosed herein are memory cells and memory arrays, as well as related methods and devices. For example, in some embodiments, a memory device may include: a support having a surface; and a three-dimensional array of memory cells on the surface of the support, wherein individual memory cells include a transistor and a capacitor, and a channel of the transistor in an individual memory cell is oriented parallel to the surface.