A method of forming an array of cross point memory cells comprises using two, and only two, masking steps to collectively pattern within the array spaced lower first lines, spaced upper second lines which cross the first lines, and individual programmable devices between the first lines and the second lines where such cross that have an upwardly open generally U-shape vertical cross-section of programmable material laterally between immediately adjacent of the first lines beneath individual of the upper second lines. Arrays of cross point memory cells independent of method of manufacture are disclosed.

An antifuse One-Time-Programmable memory cell includes a substrate, a select transistor formed on the substrate, and an antifuse capacitor formed on the substrate. The select transistor includes a first gate dielectric layer formed on the substrate, a first gate formed on the gate dielectric layer, a first high-voltage junction formed in the substrate, and a second high-voltage junction formed in the substrate. A source and a drain for the select transistor are formed by the first high-voltage junction and the second high-voltage junction. The antifuse capacitor includes a second gate dielectric layer formed on the substrate, a second gate formed on the gate dielectric layer, a third high-voltage junction formed in the substrate, and a fourth high-voltage junction formed in the substrate. A source and a drain for the antifuse capacitor are respectively formed by the third high-voltage junction and the fourth high-voltage junction.

A semiconductor structure includes a substrate; a first dielectric layer disposed over the substrate; a transistor disposed within the first dielectric layer; a second dielectric layer disposed over the first dielectric layer; and a capacitor disposed within the second dielectric layer and electrically connected to the transistor, wherein the capacitor includes a first electrode, a dielectric stack disposed over the first electrode, and a second electrode disposed over the dielectric stack, the dielectric stack includes a ferroelectric layer and an electrostrictive layer. Further, a method of manufacturing a semiconductor structure includes disposing an electrostrictive material over a first electrode layer; disposing a ferroelectric material over the first electrode layer; removing a portion of the ferroelectric material to form the ferroelectric material; and removing a portion of the electrostrictive material to form the electrostrictive layer.

Methods and devices for reading a memory cell using multi-stage memory sensing are described. The memory cell may be coupled to a digit line after the digit line during a read operation. A transistor may be activated to couple an amplifier capacitor with the digit line during the read operation. The transistor may be deactivated for a portion of the read operation to isolate the amplifier capacitor from the digit line while the memory cell is coupled to the digit line. The transistor may be reactivated to recouple the amplifier capacitor to the digit line to help determine the value of the memory cell.

A memory cell comprises first, second, third, and fourth transistors individually comprising a transistor gate. First and second ferroelectric capacitors individually have one capacitor electrode elevationally between the transistor gates of the first, second, third, and fourth transistors. Other memory cells are disclosed, as are arrays of memory cells.

The present invention relates to ferroelectric capacitors, transistors, memory device, and method of manufacturing ferroelectric devices. The ferroelectric capacitor includes a first electrode, a second electrode facing the first electrode, a ferroelectric layer between the first electrode and the second electrode, and an interfacial layer between the ferroelectric layer and the first electrode or between the ferroelectric layer and the second electrode. The ferroelectric layer includes hafnium-based oxide. The interfacial layer includes HfO.sub.2.

Some embodiments include a memory cell having a non-ohmic device between a transistor source/drain region and a capacitor. Some embodiments include a memory cell having a transistor with a first source/drain region, a second source/drain region, and a channel region between the first and second source/drain regions. A capacitor is electrically coupled to the second source/drain region through a non-ohmic device. The non-ohmic device includes a non-ohmic-device-material which changes conductivity in response to an electrical property along the channel region. The non-ohmic-device-material has a high-resistivity-mode when the electrical property along the channel region is below a threshold level, and transitions to a low-resistivity-mode when the electrical property along the channel region meets or exceeds the threshold level. Some embodiments include a memory array.

Some embodiments include a memory cell having a non-ohmic device between a transistor source/drain region and a capacitor. Some embodiments include a memory cell having a transistor with a first source/drain region, a second source/drain region, and a channel region between the first and second source/drain regions. A capacitor is electrically coupled to the second source/drain region through a non-ohmic device. The non-ohmic device includes a non-ohmic-device-material which changes conductivity in response to an electrical property along the channel region. The non-ohmic-device-material has a high-resistivity-mode when the electrical property along the channel region is below a threshold level, and transitions to a low-resistivity-mode when the electrical property along the channel region meets or exceeds the threshold level. Some embodiments include a memory array.

The memory bit-cell formed using the ferroelectric capacitor results in a taller and narrower bit-cell compared to traditional memory bit-cells. As such, more bit-cells can be packed in a die resulting in a higher density memory that can operate at lower voltages than traditional memories while providing the much sought after non-volatility behavior. The pillar capacitor includes a plug that assists in fabricating a narrow pillar.

Ferroelectric capacitor is formed by conformably depositing a non-conductive dielectric over the etched first and second electrodes, and forming a metal cap or helmet over a selective part of the non-conductive dielectric, wherein the metal cap conforms to portions of sidewalls of the non-conductive dielectric. The metal cap is formed by applying physical vapor deposition at a grazing angle to selectively deposit a metal mask over the selective part of the non-conductive dielectric. The metal cap can also be formed by applying ion implantation with tuned etch rate. The method further includes isotopically etching the metal cap and the non-conductive dielectric such that non-conductive dielectric remains on sidewalls of the first and second electrodes but not on the third and fourth electrodes.