Embodiments of the disclosure are directed to advanced integrated circuit structure fabrication and, in particular, ferroelectric three-dimensional (3D) memory architectures. Other embodiments may be disclosed or claimed.

Embodiments of the disclosure are directed to advanced integrated circuit structure fabrication and, in particular, to three-dimensional ferroelectric random access memory (3D FRAM) devices with a sense transistor coupled to a plurality of capacitors to (among other things) help improve signal levels and scaling. Other embodiments may be disclosed or claimed.

Embodiments of the disclosure are directed to advanced integrated circuit structure fabrication and, in particular, to three-dimensional ferroelectric random access memory (3D FRAM) devices with a sense transistor coupled to a plurality of capacitors to (among other things) help improve signal levels and scaling. Other embodiments may be disclosed or claimed.

Methods, systems, and devices for on-die formation of single-crystal semiconductor structures are described. In some examples, a layer of semiconductor material may be deposited above one or more decks of memory cells and divided into a set of patches. A respective crystalline arrangement of each patch may be formed based on nearly or partially melting the semiconductor material, such that nucleation sites remain in the semiconductor material, from which respective crystalline arrangements may grow. Channel portions of transistors may be formed at least in part by doping regions of the crystalline arrangements of the semiconductor material. Accordingly, operation of the memory cells may be supported by lower circuitry (e.g., formed at least in part by doped portions of a crystalline semiconductor substrate), and upper circuitry (e.g., formed at least in part by doped portions of a semiconductor deposited over the memory cells and formed with a crystalline arrangement in-situ).

Methods, systems, and devices for on-die formation of single-crystal semiconductor structures are described. In some examples, a layer of semiconductor material may be deposited above one or more decks of memory cells and divided into a set of patches. A respective crystalline arrangement of each patch may be formed based on nearly or partially melting the semiconductor material, such that nucleation sites remain in the semiconductor material, from which respective crystalline arrangements may grow. Channel portions of transistors may be formed at least in part by doping regions of the crystalline arrangements of the semiconductor material. Accordingly, operation of the memory cells may be supported by lower circuitry (e.g., formed at least in part by doped portions of a crystalline semiconductor substrate), and upper circuitry (e.g., formed at least in part by doped portions of a semiconductor deposited over the memory cells and formed with a crystalline arrangement in-situ).

Methods, systems, and devices for deck selection layouts in a memory device are described. In some implementations, a tile of a memory array may be associated with a level above a substrate, and may include a set of memory cells, a set of digit lines, and a set of word lines. Selection transistors associated with a tile of memory cells may be operable for coupling digit lines of the tile with circuitry outside the tile, and may be activated by various configurations of one or more access lines, where the various configurations may be implemented to trade off or otherwise support design and performance characteristics such as power consumption, layout complexity, operational complexity, and other characteristics. Such techniques may be implemented for other aspects of tile operations, including memory cell shunting or equalization, tile selection using transistors of a different level, or signal development, or various combinations thereof.

A gated ferroelectric memory cell includes a dielectric material layer disposed over a substrate, a metallic bottom electrode, a ferroelectric dielectric layer contacting a top surface of the bottom electrode, a pillar semiconductor channel overlying the ferroelectric dielectric layer and capacitively coupled to the metallic bottom electrode through the ferroelectric dielectric layer, a gate dielectric layer including a horizontal gate dielectric portion overlying the ferroelectric dielectric layer and a tubular gate dielectric portion laterally surrounding the pillar semiconductor channel, a gate electrode strip overlying the horizontal gate dielectric portion and laterally surrounding the tubular gate dielectric portion and a metallic top electrode contacting a top surface of the pillar semiconductor channel.

A semiconductor structure and method for forming the semiconductor are provided. The semiconductor structure includes a first electrode comprising a first portion, a second portion, and a sheet portion connecting the first portion to the second portion. A ferroelectric material is over the sheet portion. A second electrode is over the ferroelectric material.

Systems, methods, and apparatuses are provided for self-aligned etch back for vertical three dimensional (3D) memory. One example method includes depositing layers of a first dielectric material, a semiconductor material, and a second dielectric material to form a vertical stack, forming first vertical openings to form elongated vertical, pillar columns with first vertical sidewalls in the vertical stack, and forming second vertical openings through the vertical stack to expose second vertical sidewalls. Further, the example method includes removing portions of the semiconductor material to form first horizontal openings and depositing a fill in the first horizontal openings. The method can further include forming third vertical openings to expose third vertical sidewalls in the vertical stack and selectively removing the fill material to form a plurality of second horizontal openings in which to form horizontally oriented storage nodes.

A system on chip (SOC) integrated circuit device having an incorporated ferroelectric memory configured to be selectively refreshed, or not, depending on different operational modes. The ferroelectric memory is formed of an array of ferroelectric memory elements (FMEs) characterized as non-volatile, read-destructive semiconductor memory cells each having at least one ferroelectric layer. The FMEs can include FeRAM, FeFET or FTJ constructions. A read/write circuit writes data to the FMEs and subsequently reads back data from the FMEs responsive to respective write and read signals supplied by a processor circuit of the SOC. A refresh circuit is selectively enabled in a first normal mode to refresh the FMEs after a read operation, and is selectively disabled in a second exception mode so that the FMEs are not refreshed after a read operation. The FMEs can be used as a main memory, a cache, a buffer, an OTP, a keystore, etc.