A new class of logic gates are presented that use non-linear polar material. The logic gates include multi-input majority gates. Input signals in the form of digital signals are driven to non-linear input capacitors on their respective first terminals. The second terminals of the non-linear input capacitors are coupled a summing node which provides a majority function of the inputs. In the multi-input majority or minority gates, the non-linear charge response from the non-linear input capacitors results in output voltages close to or at rail-to-rail voltage levels. In some examples, the nodes of the non-linear input capacitors are conditioned once in a while to preserve function of the multi-input majority gates.

Some embodiments include an integrated assembly having pillars arranged in an array. The pillars have channel regions between upper and lower source/drain regions. Gating structures are proximate to the channel regions and extend along a row direction. Digit lines are beneath the pillars, extend along a column direction, and are coupled with the lower source/drain regions. Linear structures are above the pillars and extend along the column direction. Bottom electrodes are coupled with the upper source/drain regions. The bottom electrodes have horizontal segments adjacent the upper source/drain regions and have vertical segments extending upwardly from the horizontal segments. The vertical segments are adjacent to lateral sides of the linear structures. Ferroelectric-insulative-material and top-electrode-material are over the bottom electrodes. A slit passes through the top-electrode-material, is directly over one of the linear structures, and extends along the column direction.

A semiconductor device includes a bottom electrode, a top electrode, a sidewall spacer, and a data storage element. The sidewall spacer is disposed aside the top electrode. The data storage element is located between the bottom electrode and the top electrode, and includes a ferroelectric material. The data storage element has a peripheral region which is disposed beneath the sidewall spacer and which has at least 60% of ferroelectric phase. A method for manufacturing the semiconductor device and a method for transforming a non-ferroelectric phase of a ferroelectric material to a ferroelectric phase are also disclosed.

Some embodiments include an integrated assembly having first and second pillars of semiconductor material. The first pillar includes a first source/drain region, and the second pillar includes a second source/drain region. First and second bottom electrodes are coupled with the first and second source/drain regions, respectively. The first and second source/drain regions are spaced from one another by an intervening region. First and second leaker-device-structures extend into the intervening region from the first and second bottom electrodes, respectively. Top-electrode-material extends into the intervening region and contacts the first and second leaker-device-structures. Ferroelectric-insulative-material is between the top-electrode-material and the bottom electrodes. Some embodiments include methods of forming integrated assemblies.

A semiconductor apparatus includes a plurality of semiconductor devices. The semiconductor devices each include a ferroelectric layer, a conductive metal oxide layer, and a semiconductor layer, between two electrodes. The conductive metal oxide layer may be between the ferroelectric layer and the semiconductor layer. The ferroelectric layer, the conductive metal oxide layer, and the semiconductor layer may all include a metal oxide. The conductive metal oxide layer may include one or more materials selected from the group consisting of an indium oxide, a zinc oxide, a tin oxide, and any combination thereof.

A method used in forming an electronic component comprising conductive material and ferroelectric material comprises forming a non-ferroelectric metal oxide-comprising insulator material over a substrate. A composite stack comprising at least two different composition non-ferroelectric metal oxides is formed over the substrate. The composite stack has an overall conductivity of at least 1×10.sup.2 Siemens/cm. The composite stack is used to render the non-ferroelectric metal oxide-comprising insulator material to be ferroelectric. Conductive material is formed over the composite stack and the insulator material. Ferroelectric capacitors and ferroelectric field effect transistors independent of method of manufacture are also disclosed.

An integrated circuit structure comprises a substrate. An antiferroelectric gate oxide is above the substrate, the antiferroelectric gate oxide comprising a perovskite material. A gate electrode is over at least a portion of the gate oxide.

A memory is provided which comprises a capacitor including non-linear polar material. The capacitor may have a first terminal coupled to a node (e.g., a storage node) and a second terminal coupled to a plate-line. The capacitors can be a planar capacitor or non-planar capacitor (also known as pillar capacitor). The memory includes a transistor coupled to the node and a bit-line, wherein the transistor is controllable by a word-line, wherein the plate-line is parallel to the bit-line. The memory includes a refresh circuitry to refresh charge on the capacitor periodically or at a predetermined time. The refresh circuit can utilize one or more of the endurance mechanisms. When the plate-line is parallel to the bit-line, a specific read and write scheme may be used to reduce the disturb voltage for unselected bit-cells. A different scheme is used when the plate-line is parallel to the word-line.

Some embodiments include an integrated assembly having first and second pillars of semiconductor material laterally offset from one another. The pillars have source/drain regions and channel regions vertically offset from the source/drain regions. Gating structures pass across the channel regions, and extend along a first direction. An insulative structure is over regions of the first and second pillars, and extends along a second direction which is crosses the first direction. Bottom electrodes are coupled with the source/drain regions. Leaker-device-structures extend upwardly from the bottom electrodes. Ferroelectric-insulative-material is laterally adjacent to the leaker-device-structures and over the regions of the bottom electrodes. Top-electrode-material is over the ferroelectric-insulative-material and is directly against the leaker-device-structures. Some embodiments include methods of forming integrated assemblies.

To compensate switching of a dielectric component of a non-linear polar material based capacitor, an explicit dielectric capacitor is added to a memory bit-cell and controlled by a signal opposite to the signal driven on a plate-line.