Embodiments of 3D memory devices and methods for forming the same are disclosed. In an example, a 3D memory device includes a substrate, a memory stack, and a NAND memory string. The memory stack includes a plurality of interleaved gate conductive layers and gate-to-gate dielectric layers above the substrate. Each of the gate-to-gate dielectric layers includes a silicon nitride layer. The NAND memory string extends vertically through the interleaved gate conductive layers and gate-to-gate dielectric layers of the memory stack.

An electronic device comprising first blocks and second blocks of an array comprising memory cells. The memory cells in the first and second blocks comprise memory pillars extending through a stack. The memory pillars comprise a charge blocking material laterally adjacent to the stack, a storage nitride material laterally adjacent to the charge blocking material, a tunnel dielectric material laterally adjacent to the storage nitride material, a channel material laterally adjacent to the tunnel dielectric material, and a fill material between opposing sides of the channel material. One or more of the storage nitride material and the tunnel dielectric material in the first blocks differ in thickness or in material composition from one or more of the storage nitride material and the tunnel dielectric material in the second blocks. Additional electronic devices are disclosed, as are methods of forming an electronic device and related systems.

A device which can be implemented on a single packaged integrated circuit or a multichip module comprises a plurality of non-volatile memory cells, and logic to use a physical unclonable function to produce a key and to store the key in a set of non-volatile memory cells in the plurality of non-volatile memory cells. The physical unclonable function can use entropy derived from non-volatile memory cells in the plurality of non-volatile memory cells to produce a key. Logic is described to disable changes to data in the set of non-volatile memory cells, and thereby freeze the key after it is stored in the set.

Some embodiments include an integrated assembly having a source structure, and having a stack of alternating conductive levels and insulative levels over the source structure. Cell-material-pillars pass through the stack. The cell-material-pillars are arranged within a configuration which includes a first memory-block-region and a second memory-block-region. The cell-material-pillars include channel material which is electrically coupled with the source structure. Memory cells are along the conductive levels and include regions of the cell-material-pillars. A panel is between the first and second memory-block-regions. The panel has a first material configured as a container shape. The container shape defines opposing sides and a bottom of a cavity. The panel has a second material within the cavity. The second material is compositionally different from the first material. Some embodiments include methods of forming integrated assemblies.

A semiconductor memory device has a NOR-type memory cell array, a crossbar array, an entry gate, and a column selecting/signal processing unit. The crossbar array has a plurality of rows and columns, variable resistor elements formed in intersections of rows and columns respectively. The entry gate arranged between the memory cell array and the crossbar array, connects a selected bit line of the memory cell array to the crossbar array based on a selection signal. The column selecting/signal processing unit has a column writing unit, a column reading unit, and a NOR writing unit. The column writing unit writes data read from the memory cell array to a selected column of the crossbar array. The column reading unit reads data of the selected column of the crossbar array. The NOR writing unit at least writes data read by the column writing unit to the memory cell array.

A 3D AND flash memory device includes a gate stack structure, a channel pillar, a first and a second conductive pillars, a charge storage structure, and a protective cap. The gate stack structure is disposed on a dielectric substrate and includes gate layers and insulating layers alternately stacked with each other. The channel pillar penetrates through the gate stack structure.

The first and the second conductive pillars are disposed in the channel pillar and penetrate through the gate stack structure, and the first and the second conductive pillars are separated from each other and each connected to the channel pillar. The charge storage structure is disposed between the gate layers and a sidewall of the channel pillar. The protective cap covers at least a top surface of the channel pillar and isolates the first conductive pillar and the second conductive pillar from a top gate layer of the gate layers.

A 3-dimensional vertical memory string array includes high-speed ferroelectric field-effect transistor (FET) cells that are low- cost, low-power, or high-density and suitable for SCM applications. The memory circuits of the present invention provide random-access capabilities. The memory string may be formed above a planar surface of substrate and include a vertical gate electrode extending lengthwise along a vertical direction relative to the planar surface and may include (i) a ferroelectric layer over the gate electrode, (ii) a gate oxide layer; (iii) a channel layer provided over the gate oxide layer; and (iv) conductive semiconductor regions embedded in and isolated from each other by an oxide layer, wherein the gate electrode, the ferroelectric layer, the gate oxide layer, the channel layer and each adjacent pair of semiconductor regions from a storage transistor of the memory string, and wherein the adjacent pair of semiconductor regions serve as source and drain regions of the storage transistor.

A memory device includes pages arranged in columns and each constituted by a plurality of memory cells on a substrate, voltages applied to a first gate conductor layer, a second gate conductor layer, a first impurity layer, and a second impurity layer in each memory cell included in each of the pages are controlled to perform a page write operation of retaining, inside a channel semiconductor layer, a group of positive holes generated by an impact ionization phenomenon or by a gate-induced drain leakage current, the voltages applied to the first gate conductor layer, the second gate conductor layer, the first impurity layer, and the second impurity layer are controlled to perform a page erase operation of discharging the group of positive holes from inside the channel semiconductor layer, the first impurity layer of the memory cell is connected to a source line, the second impurity layer thereof is connected to a bit line, one of the first gate conductor layer or the second gate conductor layer is connected to a word line, and the other of the first gate conductor layer or the second gate conductor layer is connected to a first driving control line, the bit line is connected to a sense amplifier circuit with a first switch circuit therebetween, and in a page refresh operation, page data in a first group of memory cells belonging to a first page is read to the sense amplifier circuits, the first switch circuit is put in a non-conducting state, the page erase operation of the first group of memory cells is performed, the first switch circuit is put in a conducting state, and the page write operation of writing the page data in the sense amplifier circuits back to the first group of memory cells is performed.

A memory device includes a plurality of pages arranged in columns, each page is constituted by a plurality of memory cells arranged in rows on a substrate, the memory cells included in the page are memory cells of a plurality of semiconductor base materials that stand on the substrate in a vertical direction or that extend in a horizontal direction along the substrate, voltages applied to a first gate conductor layer, a second gate conductor layer, a first impurity layer, and a second impurity layer in each memory cell are controlled to perform a page write operation of retaining, inside a channel semiconductor layer, a group of positive holes generated by an impact ionization phenomenon or by a gate-induced drain leakage current, the voltages applied to the first gate conductor layer, the second gate conductor layer, the first impurity layer, and the second impurity layer are controlled to perform a page erase operation of discharging the group of positive holes from inside the channel semiconductor layer, and all memory cells included in a first page subjected to the page erase operation perform the page write operation at least once.

An operation method of a multi-bits read only memory includes a step of applying a gate voltage to a conductive gate, a first voltage to a first electrode, and a second voltage to a second electrode. The multi-bits read only memory of the present invention includes a substrate and a transistor structure with the conductive gate mounted between the first electrode and the second electrode, a first oxide located between the first electrode and the conductive gate, and a second oxide located between the second electrode and the conductive gate. The present invention creates an initial state wherein the transistor structure is not conducting, an intermediate state wherein the first oxide is punched through by the first voltage, and a fully opened state wherein both the first oxide and the second oxide are punched through. The aforementioned states allow storage of multiple bits on the read only memory.