A method for manufacturing resistive random access memories, each resistive random access memory including first and second electrodes separated by a layer of active material, the method including producing connector elements with a step Cp along a first direction, each connector element having a width Cb along the first direction; producing a plurality of first electrodes with a step Ep along the first direction, each first electrode having a first end surface and a second end surface, the second end surface having a width Eb along the first direction and an area greater than the area of the first end surface; wherein: 0<Ep−Eb≦Cp−Cb and:Eb<Cp−Cb such that, for each connector element, a first electrode is in contact, via its second end surface, with the connector element, and each first electrode is only in contact, via its second end surface, with at the most one connector element.

The present disclosure generally relates to memory devices and methods of forming the same. More particularly, the present disclosure relates to resistive random-access (ReRAM) memory devices. The present disclosure provides a memory device including a first electrode, a dielectric cap above the first electrode, a second electrode laterally adjacent to the first electrode, in which an upper surface of the second electrode is substantially coplanar with an upper surface of the dielectric cap, and a resistive layer between the first electrode and the second electrode. An edge of the first electrode is electrically coupled to an edge of the second electrode by at least the resistive layer.

Electrical contacts may be formed by forming dielectric liners along sidewalls of a dielectric structure, forming sacrificial liners over and transverse to the dielectric liners along sidewalls of a sacrificial structure, selectively removing portions of the dielectric liners at intersections of the dielectric liners and sacrificial liners to form pores, and at least partially filling the pores with a conductive material. Nano-scale pores may be formed by similar methods. Bottom electrodes may be formed and electrical contacts may be structurally and electrically coupled to the bottom electrodes to form memory devices. Nano-scale electrical contacts may have a rectangular cross-section of a first width and a second width, each width less than about 20 nm. Memory devices may include bottom electrodes, electrical contacts having a cross-sectional area less than about 150 nm.sup.2 over and electrically coupled to the bottom electrodes, and a cell material over the electrical contacts.

Multi-time programmable (MTP) random access memory (RRAM) devices and methods for forming a MTP RRAM device are disclosed. The method includes providing a substrate. The substrate is prepared with at least a first region for accommodating one or more multi-programmable based resistive random access memory (RRAM) cell. A fin-type based selector is provided over the substrate in the first region. A storage element of the RRAM cell is formed over the fin-type based selector. The fin-type based selector is coupled in series with the storage element of the RRAM cell.

According to one embodiment, a memory device includes a superlattice structure portion containing first chalcogen-compound layers and second chalcogen-compound layers differing in composition from the first chalcogen-compound layers are alternately deposited, a first layer provided on one of main surfaces of the superlattice structure portion in a deposition direction thereof, which has a larger energy gap than that of the superlattice structure portion, and a second layer provided on the other main surface of the superlattice structure portion in the deposition direction, which has a larger energy gap than that of the superlattice structure portion.

A resistive memory structure, for example, phase change memory structure, includes one access device and two or more resistive memory cells. Each memory cell is coupled to a rectifying device to prevent parallel leak current from flowing through non-selected memory cells. In an array of resistive memory bit structures, resistive memory cells from different memory bit structures are stacked and share rectifying devices.

Methods of forming semiconductor structures that include bodies of a semiconductor material disposed between rails of a dielectric material are disclosed. Such methods may include filling a plurality of trenches in a substrate with a dielectric material and removing portions of the substrate between the dielectric material to form a plurality of openings. In some embodiments, portions of the substrate may be undercut to form a continuous void underlying the bodies and the continuous void may be filled with a conductive material. In other embodiments, portions of the substrate exposed within the openings may be converted to a silicide material to form a conductive material under the bodies. For example, the conductive material may be used as a conductive line to electrically interconnect memory device components. Semiconductor structures and devices formed by such methods are also disclosed.

The present invention relates to a resistive random access memory device having a nano-scale tip, memory array using the same and fabrication method thereof. Especially, the present invention provides a technique forming a bottom electrode having an upwardly protruding tapered tip structure through etching a semiconductor substrate in order that an electric field is focused on the tip of the bottom electrode across a top electrode and that a region where conductive filaments are formed is maximally minimized or localized.

Structures for a resistive memory element and methods of forming a structure for a resistive memory element. The resistive memory element includes a first switching layer, a second switching layer, a conductive spacer, a first electrode, and a second electrode. The first switching layer includes a portion positioned between the first electrode and the conductive spacer, the second switching layer includes a portion positioned between the second electrode and the conductive spacer, and the conductive spacer is positioned between the portion of the first switching layer and the portion of the second switching layer.

A memory device may include at least one inert electrode, at least one mask element arranged over the at least one inert electrode, a switching layer arranged over the at least one mask element and the at least one inert electrode, and at least one active electrode arranged over the switching layer. Both of the at least one mask element and the switching layer may be in contact with a top surface of the at least one inert electrode. The switching layer in this memory device may thus include corners at which the conductive filaments may be confined. This memory device may be formed with a process that may utilize the at least one mask element to help reduce the chances of shorting between the inert and active electrodes.