A disclosed semiconductor device includes a memory cell with a first terminal, a second terminal, a memory element having a first resistance state and a second resistance state, and a nonlinear element, and a drive controller that performs a first operation that allows the memory element to be in the first resistance state, a second operation that allows the memory element to be in the second resistance state, a third operation in which the voltage of the first and second terminals is caused to be different from each other and a value of electric current flowing between the first terminal and the second terminal is caused to be limited to a first current value to determine the resistance state, and a fourth operation in which the current value is caused to be limited to a second current value. The drive controller performs the fourth operation after at least one of the first to third operations.

A diode is made of a p-type layer and an n-type layer connected in series between a bottom and top electrode. The p-type and n-type layers have a thickness below 20 nm. A p-type dopant concentration and an n-type dopant concentration are high enough to keep a total resistance across the diode at less than 250Ω when the diode is forward biased while still retaining the characteristics of a diode. In some embodiments, the ratio of an ON current to an OFF current is greater than 2.5×10.sup.4. Alternate embodiments of the diode, arrays of diodes and methods of making diodes are disclosed. Example arrays include memory arrays using diodes and phase change memories (PCMs) connected in series as array elements. The arrays can be stacked in layers and can be made/embodied in the back-end-of-the line (BEOL).

The present disclosure relates generally to structures in semiconductor devices and methods of forming the same. The present disclosure provides a semiconductor device including a first device region and a second device region. The first device region includes a first metal layer, a first via structure over the first metal layer, a second via structure over the first via structure, and a second metal layer over the second via structure. The first via structure and the second via structure electrically couple the second metal layer to the first metal layer. The second device region includes a third metal layer, a contact structure over the third metal layer, a memory cell structure over the contact structure, and a fourth metal layer over the memory cell structure. The first via structure and the contact structure are made of the same material.

Methods of manufacturing memory devices having memory cells and corresponding selectors, and associated systems and devices, are disclosed herein. In one embodiment, a method of manufacturing a memory device includes (a) removing a protection layer formed over the memory cells and (b) forming a cap layer over the memory cells before forming a conductive via through the memory device. The cap layer is configured to protect the memory cells during operation and can comprise a resistive material. The protection layer can be more efficiently removed with improved process margin and less device health impact using a polishing process before the conductive via is formed, thus increasing the manufacturing margin of the memory device.

A memory device may be provided, including a base layer; an insulating layer arranged over the base layer, where the insulating layer may include a recess having opposing side walls; a first electrode arranged along the opposing side walls of the recess; a switching element arranged along the first electrode; a second electrode arranged along the switching element; and a capping layer arranged over the recess, where the capping layer may at least partially overlap the first electrode, the switching element and the second electrode.

An integrated circuit device includes a substrate; an integrated circuit area disposed on the substrate and comprising a dielectric stack; a seal ring disposed in the dielectric stack and around a periphery of the integrated circuit area; a cap layer on the dielectric stack; a trench around the seal ring and exposing a sidewall of the dielectric stack; a memory storage structure disposed on the cap layer; and a moisture blocking layer continuously covering the integrated circuit area and the memory storage structure. The moisture blocking layer extends to the sidewall of the dielectric stack, thereby sealing a boundary between two adjacent dielectric films in the dielectric stack.

A memory structure can include a memory cell and a first barrier layer having a maximum hydrogen diffusion coefficient of 1×10.sup.−17 cm.sup.2/s, said first barrier layer adjacent to the memory cell to minimize contaminant movement to or from the memory cell.

According to one embodiment, a memory device includes a first electrode, a second electrode, and a resistive layer provided between the first electrode and the second electrode, containing at least one of antimony (Sb) and bismuth (Bi) as a first element, and tellurium (Te) as a second element, and having a variable resistance value. The resistive layer includes a first layer having a hexagonal crystal structure containing the first element and the second element. The first layer contains a group 14 element as a third element.

Some embodiments relate to an integrated circuit including one or more memory cells arranged over a semiconductor substrate between an upper metal interconnect layer and a lower metal interconnect layer. A memory cell includes a bottom electrode disposed over the lower metal interconnect layer, a data storage or dielectric layer disposed over the bottom electrode, and a top electrode disposed over the data storage or dielectric layer. An upper surface of the top electrode is in direct contact with the upper metal interconnect layer without a via or contact coupling the upper surface of the top electrode to the upper metal interconnect layer. Sidewall spacers are arranged along sidewalls of the top electrode, and have bottom surfaces that rest on an upper surface of the data storage or dielectric layer.

The present disclosure includes memory cells having resistors, and methods of forming the same. An example method includes forming a first conductive line, forming a second conductive line, and forming a memory element between the first conductive line and the second conductive line. Forming the memory element can include forming one or more memory materials, and forming a resistor in series with the one or more memory materials. The resistor can be configured to reduce a capacitive discharge through the memory element during a state transition of the memory element.