An integrated circuit device can include a plurality of nonvolatile memory elements having values that vary randomly or pseudo-randomly from one another; a selection circuit configured to select a plurality of nonvolatile memory elements that vary randomly or pseudo-randomly in response to a received challenge value; and sense circuits configured to generate a response value based on the values of the selected nonvolatile memory elements. Related methods and systems are also disclosed.

A memory device is provided that includes at least one resistive memory cell, a negative capacitance field effect transistor (NC-FET) serving as a voltage amplifier, and a switch enable circuit connecting NC-FET to the memory cell. The NC-FET includes a regular FET having a metal gate terminal and a ferroelectric capacitor. The NC-FET gate terminal forms one plate of the ferroelectric (FE) capacitor. The ferroelectric capacitor includes a ferroelectric dielectric material deposited between a formed upper gate conductive contact and he metal gate terminal. To provide further flexibility, a metal layer can be deposited before the deposition of the ferroelectric material to form a MIM-like FE capacitor so that the capacitance of FE capacitance can be independently tuned by choosing the right height (H), width (W), and length (L) to achieve desired matching between |C.sub.FE| and C.sub.ox where C.sub.ox is the gate oxide capacitance and C.sub.FE is the ferroelectric capacitance.

A switching device including a GaN substrate; an unintentionally doped GaN layer on a first surface of the GaN substrate; a regrown unintentionally doped GaN layer on the unintentionally doped GaN layer; a regrowth interface between the unintentionally doped GaN layer and the regrown unintentionally doped GaN layer; a p-GaN layer on the regrown unintentionally doped GaN layer; a first electrode on the p-GaN layer; and a second electrode on a second surface of the GaN substrate.

An example apparatus can include a memory array and a memory controller. The memory array can include a first portion including a first plurality of memory cells. The memory array can further include a second portion including a second plurality of memory cells. The memory controller can be coupled to the first portion and the second portion. The memory controller can be configured to operate the first plurality of memory cells for short-term memory operations. The memory controller can be further configured to operate the second plurality of memory cells for long-term memory operations.

An object of the present invention is to provide a composition, a memory structure suitable for the composition, a manufacturing method, and an operating method for stable operation in a memory element including a chalcogen compound. In order to achieve the object, in a memory array with a cross-point structure including a first electrode line and a second electrode line intersecting each other, and a selective memory element disposed at each intersection of the first electrode line and the second electrode line and being a chalcogen compound, the present invention may provide the memory array with a cross-point structure including the first electrode line formed on a substrate, a first functional electrode formed between the first electrode line and the selective memory element, and a second functional electrode formed between the second electrode line and the selective memory element, wherein the first functional electrode is formed as a line along the first electrode line.

The apparatuses and methods described herein may operate to measure a voltage difference between a selected access line and a selected sense line associated with a selected cell of a plurality of memory cells of a memory array. The voltage difference may be compared with a reference voltage specified for a memory operation. A selection voltage(s) applied to the selected cell for the memory operation may be adjusted responsive to the comparison, such as to dynamically compensate for parasitic voltage drop.

A resistive memory device includes word lines, first memory cells, second memory cells, bit lines, source lines, and a driver. The driver provides a forming voltage to the first memory cells and the second memory cells through the bit lines and the source lines in a forming process. A first connection length along the bit lines and the source lines between the first memory cells and the driver is longer than a second connection length along the bit lines and the source lines between the second memory cells and the driver. The forming process is performed to the first memory cells before the forming process is performed to the second memory cells. A first value of the forming voltage provided to the first memory cells is less than a second value of the forming voltage provided to the second memory cells.

The present invention disclosures a RRAM cell structure, comprising a first transistor and a second transistor which are connected in parallel and commonly connected to a resistive switching device; wherein, the first transistor is set with a first gate, a first source and a first drain, a first control signal is applied to the first gate, and a first source signal is applied to the first source; the second transistor is set with a second gate, a second source and a second drain, a second control signal is applied to the second gate, and a second source signal is applied to the second source; the first drain is connected with the second drain, which are commonly connected to one terminal of the resistive switching device, and a bit signal is applied to another terminal of the resistive switching device. The present invention uses cell area of a traditional 1T1R to manufacture a 2T1R cell structure, which can take into account various operating voltage requirements of the resistive switching device simultaneously, so as to significantly improve cell performances thereof.

The present invention is directed to a magnetic memory cell including a magnetic tunnel junction (MTJ) memory element and a two-terminal bidirectional selector coupled in series between two conductive lines. The MTJ memory element includes a magnetic free layer, a magnetic reference layer, and an insulating tunnel junction layer interposed therebetween. The two-terminal bidirectional selector includes bottom and top electrodes, first and third volatile switching layers interposed between the bottom and top electrodes, and a second volatile switching layer interposed between the first and third volatile switching layers. The bottom and top electrodes each independently include one of titanium nitride or iridium. The first and third volatile switching layers each include tantalum oxide and silver. The second volatile switching layer includes hafnium oxide and has a higher electrical resistance than the first and third volatile switching layers.

An example apparatus can include a memory array and a memory controller. The memory array can include a first portion including a first plurality of memory cells. The memory array can further include a second portion including a second plurality of memory cells. The memory controller can be coupled to the first portion and the second portion. The memory controller can be configured to operate the first plurality of memory cells for short-term memory operations. The memory controller can be further configured to operate the second plurality of memory cells for long-term memory operations.