Provided is a memristor including an active electrode made of a first conductive material including an active metal; an inert electrode spaced from and facing toward the active electrode and made of a second conductive material having an ionization energy greater than the ionization energy of the first conductive material; and a resistive switching layer including: a porous insulating layer disposed between the active electrode and the inert electrode, wherein the porous insulating layer has through-channel holes defined therein extending from a bottom face to a top face thereof; and conductive filaments respectively formed inside the through-channel holes.

A semiconductor device with a large storage capacity per unit area is provided. The semiconductor device includes a first insulator including a first opening, a first conductor that is over the first insulator and includes a second opening, a second insulator that is over the first insulator and includes a third opening, and an oxide penetrating the first opening, the second opening, and the third opening. The oxide includes a first region at least in the first opening, a second region at least in the second opening, and a third region at least in the third opening. The resistances of the first region and the third region are lower than the resistance of the second region.

A vertical nonvolatile memory device including memory cell strings using a resistance change material is provided. Each of the memory cell strings of the nonvolatile memory device includes a semiconductor layer extending in a first direction; a plurality of gates and a plurality of insulators alternately arranged in the first direction; a gate insulating layer extending in the first direction between the plurality of gates and the semiconductor layer and between the plurality of insulators and the semiconductor layer; and a resistance change layer extending in the first direction on a surface of the semiconductor layer. The resistance change layer includes a metal-semiconductor oxide including a mixture of a semiconductor material of the semiconductor layer and a transition metal oxide.

A semiconductor structure includes a substrate; a resistance variable layer disposed over the substrate; a gate structure disposed over the resistance variable layer; a dielectric layer disposed over the resistance variable layer and surrounding the gate structure; a first contact plug disposed over the resistance variable layer and extending through the dielectric layer; and a second contact plug disposed over the resistance variable layer and opposite to the first contact plug and extending through the dielectric layer, wherein the resistance variable layer is semiconductive and ferroelectric,

A method is presented for enabling heat dissipation in resistive random access memory (RRAM) devices. The method includes forming a first thermal conducting layer over a bottom electrode, depositing a metal oxide liner over the first thermal conducting layer, forming a second thermal conducting layer over the metal oxide liner, recessing the second thermal conducting layer to expose the first thermal conducting layer, and forming a top electrode in direct contact with the first and second thermal conducting layers.

A nonvolatile memory device and a method of operating the same are provided. The nonvolatile memory device may include a memory cell array having a vertical stack-type structure, a control logic, and a bit line. The memory cell array may include memory cells that each include corresponding portions of a semiconductor layer and a resistance change layer. The control logic, in a read operation, may be configured to apply a first voltage to a non-select memory cell and a second voltage to a non-select memory cell. The first voltage turns on current only in the semiconductor layer portion of the non-select memory cell. The second voltage turns on current in both the semiconductor layer and resistance change layer portions of the select memory cell. The bit line may be configured to apply a read voltage to the select memory cell during the read operation.

A method is presented for enabling heat dissipation in resistive random access memory (RRAM) devices. The method includes forming a first thermal conducting layer over a bottom electrode, depositing a metal oxide liner over the first thermal conducting layer, forming a second thermal conducting layer over the metal oxide liner, recessing the second thermal conducting layer to expose the first thermal conducting layer, and forming a top electrode in direct contact with the first and second thermal conducting layers.

A semiconductor device may include: a first conductive line; a second conductive line disposed over the first conductive line to be spaced apart from the first conductive line; a variable resistance layer disposed over the first conductive line and below the second conductive line; at least one of a first dielectric layer or a second dielectric layer; at least one of a first contact or a second contact; and at least one of a first doped selector layer or a second doped selector layer.

A method is presented for enabling heat dissipation in resistive random access memory (RRAM) devices. The method includes forming a first thermal conducting layer over a bottom electrode, depositing a metal oxide liner over the first thermal conducting layer, forming a second thermal conducting layer over the metal oxide liner, recessing the second thermal conducting layer to expose the first thermal conducting layer, and forming a top electrode in direct contact with the first and second thermal conducting layers.

A chalcogen compound layer exhibiting ovonic threshold switching characteristics, a switching device, a semiconductor device, and/or a semiconductor apparatus including the same are provided. The switching device and/or the semiconductor device may include two or more chalcogen compound layers having different energy band gaps. Alternatively, the switching device and/or semiconductor device may include a chalcogen compound layer having a concentration gradient of an element of boron (B), aluminum (Al), scandium (Sc), manganese (Mn), strontium (Sr), and/or indium (In) in a thickness direction thereof. The switching device and/or a semiconductor device may exhibit stable switching characteristics while having a low off-current value (leakage current value).