An apparatus includes a semiconductor substrate; an access transistor including channel, source and drain regions arranged in a vertical direction to the semiconductor substrate and a gate-electrode facing to the channel region; a storage capacitor coupled to one of the source and drain regions; a bit-line coupled to the other of the source and drain regions; and a pull-out-electrode connected to the bit-line; wherein surfaces of the source and drain regions and the pull-out-electrode on the bit-line side is arranged at substantially the same height from the upper surface of the semiconductor substrate.

An apparatus includes a semiconductor substrate; an access transistor including channel, source and drain regions arranged in a vertical direction to the semiconductor substrate and a gate-electrode facing to the channel region; a storage capacitor coupled to one of the source and drain regions; a bit-line coupled to the other of the source and drain regions; and a pull-out-electrode connected to the bit-line; wherein surfaces of the source and drain regions and the pull-out-electrode on the bit-line side is arranged at substantially the same height from the upper surface of the semiconductor substrate.

A memory structure includes a spacer between a first side of a wordline conductor and a bitline conductor. A semiconductor material has horizontal portions extending from the bitline conductor along a top and bottom of the wordline conductor and has a contact portion extending along a second side of the wordline conductor between and connecting the horizontal portions. A high-κ dielectric is between the semiconductor material and the wordline conductor. A capacitor has a first conductor, a second conductor, and an insulator between the first and second conductors, where the first conductor contacts the contact portion of the semiconductor material along the first side of the wordline conductor, and the second conductor connects to a ground terminal.

A memory structure includes a spacer between a first side of a wordline conductor and a bitline conductor. A semiconductor material has horizontal portions extending from the bitline conductor along a top and bottom of the wordline conductor and has a contact portion extending along a second side of the wordline conductor between and connecting the horizontal portions. A high-κ dielectric is between the semiconductor material and the wordline conductor. A capacitor has a first conductor, a second conductor, and an insulator between the first and second conductors, where the first conductor contacts the contact portion of the semiconductor material along the first side of the wordline conductor, and the second conductor connects to a ground terminal.

On a substrate, dynamic flash memory cell transistors and, on their outside, driving-signal processing circuit transistors are disposed. A source line wiring layer, a bit line wiring layer, a plate line wiring layer, and a word line wiring layer extend in the horizontal direction relative to the substrate and connect, from the outside of a dynamic flash memory region, in the perpendicular direction, to lead-out wiring layers on an insulating layer. The transistors in driving-signal processing circuit regions connect, via multilayered wiring layers, to upper wiring layers on the insulating layer. A high-thermal-conductivity layer is disposed over the entirety of the dynamic flash memory region and in a portion above the bit line wiring layer.

On a substrate, dynamic flash memory cell transistors and, on their outside, driving-signal processing circuit transistors are disposed. A source line wiring layer, a bit line wiring layer, a plate line wiring layer, and a word line wiring layer extend in the horizontal direction relative to the substrate and connect, from the outside of a dynamic flash memory region, in the perpendicular direction, to lead-out wiring layers on an insulating layer. The transistors in driving-signal processing circuit regions connect, via multilayered wiring layers, to upper wiring layers on the insulating layer. A high-thermal-conductivity layer is disposed over the entirety of the dynamic flash memory region and in a portion above the bit line wiring layer.

A microelectronic device comprises array regions individually comprising memory cells comprising access devices and storage node device, digit lines coupled to the access devices and extending in a first direction, word lines coupled to the access devices and extending in a second direction orthogonal to the first direction, and control logic devices over and in electrical communication with the memory cells. The microelectronic device further comprises capacitor regions horizontally offset from the array regions in the first direction and having a dimension in the second direction greater than each individual array region in the second direction. The capacitor regions individually comprise additional control logic devices vertically overlying the memory cells, and capacitor structures within horizontal boundaries of the additional control logic devices. Related microelectronic devices, electronic systems, and methods are also described.

A microelectronic device comprises array regions individually comprising memory cells comprising access devices and storage node device, digit lines coupled to the access devices and extending in a first direction, word lines coupled to the access devices and extending in a second direction orthogonal to the first direction, and control logic devices over and in electrical communication with the memory cells. The microelectronic device further comprises capacitor regions horizontally offset from the array regions in the first direction and having a dimension in the second direction greater than each individual array region in the second direction. The capacitor regions individually comprise additional control logic devices vertically overlying the memory cells, and capacitor structures within horizontal boundaries of the additional control logic devices. Related microelectronic devices, electronic systems, and methods are also described.

A high-density low voltage ferroelectric (or paraelectric) memory bit-cell that includes a planar ferroelectric or paraelectric capacitor. The memory bit-cell comprises 1T1C configuration, where a plate-line is parallel to a word-line, or the plate-line is parallel to a bit-line. The memory bit-cell can be 1TnC, where ‘n’ is a number. In a 1TnC bit-cell, the capacitors are vertically stacked allowing for multiple values to be stored in a single bit-cell. The memory bit-cell can be multi-element FE gain bit-cell. In a multi-element FE gain bit-cell, data sensing is done with signal amplified by a gain transistor in the bit-cell. As such, higher storage density is realized using multi-element FE gain bit-cells. In some examples, the 1T1C, 1TnC, and multi-element FE gain bit-cells are multi-level bit-cells. To realize multi-level bit-cells, the capacitor is placed in a partially switched polarization state by applying different voltage levels or different time pulse widths at the same voltage level.

A ferroelectric memory structure including a substrate, a ferroelectric capacitor structure, and a switch device is provided. The ferroelectric capacitor structure is disposed on the substrate. The ferroelectric capacitor structure includes at least one first electrode, first dielectric layers, a second electrode, and a ferroelectric material layer. The at least one first electrode and the first dielectric layers are alternately stacked. The second electrode penetrates through the first electrode. The ferroelectric material layer is disposed between the first electrode and the second electrode. The switch device is electrically connected to the ferroelectric capacitor structure.