Methods, systems, and devices for thin film transistor deck selection in a memory device are described. A memory device may include memory arrays arranged in a stack of decks formed over a substrate, and deck selection components distributed among the layers to leverage common substrate-based circuitry. For example, each memory array of the stack may include a set of digit lines of a corresponding deck, and deck selection circuitry operable to couple the set of digit lines with a column decoder that is shared among multiple decks. To access memory cells of a selected memory array on one deck, the deck selection circuitry corresponding to the memory array may each be activated, while the deck selection circuitry corresponding to a non-selected memory array on another deck may be deactivated. The deck selection circuitry, such as transistors, may leverage thin-film manufacturing techniques, such as various techniques for forming vertical transistors.

An apparatus and configuring scheme where a ferroelectric capacitive input circuit can be programmed to perform different logic functions by adjusting the switching threshold of the ferroelectric capacitive input circuit. Digital inputs are received by respective capacitors on first terminals of those capacitors. The second terminals of the capacitors are connected to a summing node. A pull-up and pull-down device are coupled to the summing node. The pull-up and pull-down devices are controlled separately. During a reset phase, the pull-up and pull-down devices are turned on in a sequence, and inputs to the capacitors are set to condition the voltage on node n1. As such, a threshold for the capacitive input circuit is set. After the reset phase, an evaluation phase follows. In the evaluation phase, the output of the capacitive input circuit is determined based on the inputs and the logic function configured during the reset phase.

A semiconductor memory device is provided. The semiconductor memory device may include a semiconductor substrate; a data storage layer including capacitors disposed on the semiconductor substrate; a switching element layer on the data storage layer and including transistors connected to the respective capacitors; and a wiring layer on the switching element layer and including bit lines connected to the transistors, The respective transistors include an active pattern, a word line that crosses the active pattern such that the word line surrounds a first sidewall, a second sidewall and a top surface of the active pattern, and a ferroelectric layer between the word line and the active patter.

A semiconductor memory device is provided. The semiconductor memory device may include a semiconductor substrate; a data storage layer including capacitors disposed on the semiconductor substrate; a switching element layer on the data storage layer and including transistors connected to the respective capacitors; and a wiring layer on the switching element layer and including bit lines connected to the transistors, The respective transistors include an active pattern, a word line that crosses the active pattern such that the word line surrounds a first sidewall, a second sidewall and a top surface of the active pattern, and a ferroelectric layer between the word line and the active patter.

Described is a packaging technology to improve performance of an AI processing system. An IC package is provided which comprises: a substrate; a first die on the substrate, and a second die stacked over the first die. The first die includes memory and the second die includes computational logic. The first die comprises a ferroelectric RAM (FeRAM) having bit-cells. Each bit-cell comprises an access transistor and a capacitor including ferroelectric material. The access transistor is coupled to the ferroelectric material. The FeRAM can be FeDRAM or FeSRAM. The memory of the first die may store input data and weight factors. The computational logic of the second die is coupled to the memory of the first die. The second die is an inference die that applies fixed weights for a trained model to an input data to generate an output. In one example, the second die is a training die that enables learning of the weights.

Apparatuses, systems, and methods for ferroelectric memory (FeRAM) cell operation. An FeRAM cell may have different charge regions it can operate across. Some regions, such as dielectric regions, may operate faster, but with reduced signal on a coupled digit line. To improve the performance while maintaining increased speed, two digit lines may be coupled to the same sense amplifier, so that the FeRAM cells coupled to both digit lines contribute signal to the sense amplifier. For example a first digit line in a first deck of the memory and a second digit line in a second deck of the memory may both be coupled to the sense amplifier. In some embodiments, additional digit lines may be used as shields (e.g., by coupling the shield digit lines to a ground voltage) to further improve the signal-to-noise ratio.

Apparatuses, systems, and methods for ferroelectric memory (FeRAM) cell operation. An FeRAM cell may have different charge regions it can operate across. Some regions, such as dielectric regions, may operate faster, but with reduced signal on a coupled digit line. To improve the performance while maintaining increased speed, two digit lines may be coupled to the same sense amplifier, so that the FeRAM cells coupled to both digit lines contribute signal to the sense amplifier. For example a first digit line in a first deck of the memory and a second digit line in a second deck of the memory may both be coupled to the sense amplifier. In some embodiments, additional digit lines may be used as shields (e.g., by coupling the shield digit lines to a ground voltage) to further improve the signal-to-noise ratio.

A 3D device, the device including: a first level including logic circuits; and a second level including a plurality of memory cells, where the first level is bonded to the second level, where the bonded includes oxide to oxide bonds, and where the logic circuits include a programmable logic circuit.

A memory cell arrangement is provided that may include: a plurality of electrode layers, wherein each of the plurality of electrode layers comprises a plurality of through holes, each of the plurality of through holes extending from a first surface to a second surface of a respective electrode layer; a plurality of electrode pillars, wherein each of the plurality of electrode pillars comprises a plurality of electrode portions, wherein each of the plurality of electrode portions is disposed within a corresponding one of the plurality of through holes; wherein the respective electrode layer and a respective electrode portion of the plurality of electrode portions form a first electrode and a second electrode of a capacitor and wherein at least one memory material portion is disposed in each of the plurality of through holes in a gap between the respective electrode layer and the respective electrode portion.

Methods, systems, and devices for multiple plate line architecture for multideck memory arrays are described. A memory device may include two or more three-dimensional arrays of ferroelectric memory cells overlying a substrate layer that includes various components of support circuitry, such as decoders and sense amplifiers. Each memory cell of the array may have a ferroelectric container and a selector device. Multiple plate lines or other access lines may be routed through the various decks of the device to support access to memory cells within those decks. Plate lines or other access lines may be coupled between support circuitry and memory cells through on pitch via (OPV) structures. OPV structures may include selector devices to provide an additional degree of freedom in multideck selectivity. Various number of plate lines and access lines may be employed to accommodate different configurations and orientations of the ferroelectric containers.