An electronic device comprising a semiconductor memory is provided. The semiconductor memory includes a substrate including a cell region and a peripheral circuit region, the cell region including a first cell region and a second cell region, the first cell region being disposed closer to the peripheral circuit region than the second cell region; second lines disposed over the first lines and extending in a second direction crossing the first direction; memory cells positioned at intersections between the first lines and the second lines in the cell region; a first insulating layer positioned between the first lines, between the second line, or both, in the first cell region; and a second insulating layer positioned between the first lines and between the second lines in the second cell region. A dielectric constant of the first insulating layer is smaller than that of the second insulating layer.

According to one embodiment, a semiconductor memory device includes: a first and a second wirings; a third wiring disposed between them; a first phase change layer disposed between the first and the third wirings; a first conducting layer disposed on a first wiring side surface of the first phase change layer; a second conducting layer disposed on a third wiring side surface of the first phase change layer; a second phase change layer disposed between the third and the second wirings; a third conducting layer disposed on a third wiring side surface of the second phase change layer; and a fourth conducting layer disposed on a second wiring side surface of the second phase change layer. The first and the fourth conducting layers have coefficients of thermal conductivity larger or smaller than the coefficients of thermal conductivity of the second and the third conducting layers.

The present invention provides a multi-layer selector device exhibiting a low leakage current by controlling a threshold voltage. According to an embodiment of the present invention, the multi-layer selector device comprises: a substrate; a lower electrode layer disposed on the substrate; an insulating layer disposed on the lower electrode layer and having a via hole passing through to expose the lower electrode layer; a switching layer disposed on the lower electrode layer in the via hole, performing a switching operation by forming and destroying a conductive filament, and made of a multi-layer to control the formation of the conductive filament; and an upper electrode layer disposed on the switching layer.

A memory array, a semiconductor chip and a method for forming the memory array are provided. The memory array includes first signal lines, second signal lines and memory cells. The first signal lines extend along a first direction. The second signal lines extend along a second direction over the first signal lines. The memory cells are defined at intersections of the first and second signal lines, and respectively include a resistance variable layer, a switching layer, an electrode layer and a carbon containing dielectric layer. The switching layer is overlapped with the resistance variable layer. The electrode layer lies between the resistance variable layer and the switching layer. The carbon containing layer laterally surrounds a stacking structure including the resistance variable layer, the switching layer and the electrode layer.

Forming a semiconductor device includes forming a first conductive line on a substrate, forming a memory cell including a switching device and a data storage element on the first conductive line, and forming a second conductive line on the memory cell. Forming the switching device includes forming a first semiconductor layer, forming a first doped region by injecting a n-type impurity into the first semiconductor layer, forming a second semiconductor layer thicker than the first semiconductor layer, on the first semiconductor layer having the first doped region, forming a second doped region by injecting a p-type impurity into an upper region of the second semiconductor layer, and forming a P-N diode by performing a heat treatment process to diffuse the n-type impurity and the p-type impurity in the first doped region and the second doped region to form a P-N junction of the P-N diode in the second semiconductor layer.

Some embodiments relate to a memory device. The memory device includes a first electrode overlying a substrate. A data storage layer is disposed on the first electrode. A second electrode overlies the data storage layer. A buffer layer is disposed between the data storage layer and the second electrode.

Methods, systems, and devices for on-die formation of single-crystal semiconductor structures are described. In some examples, a layer of semiconductor material may be deposited above one or more decks of memory cells and divided into a set of patches. A respective crystalline arrangement of each patch may be formed based on nearly or partially melting the semiconductor material, such that nucleation sites remain in the semiconductor material, from which respective crystalline arrangements may grow. Channel portions of transistors may be formed at least in part by doping regions of the crystalline arrangements of the semiconductor material. Accordingly, operation of the memory cells may be supported by lower circuitry (e.g., formed at least in part by doped portions of a crystalline semiconductor substrate), and upper circuitry (e.g., formed at least in part by doped portions of a semiconductor deposited over the memory cells and formed with a crystalline arrangement in-situ).

A variable resistance memory device includes a plurality of memory cells arranged on a substrate. Each of the memory cells includes a selection element pattern and a variable resistance pattern stacked on the substrate. The selection element pattern includes a first selection element pattern having a chalcogenide material and a second selection element pattern having a metal oxide and coupled to the first selection element pattern.

A multi-layer memory device with an array having multiple memory decks of self-selecting memory cells is provided in which N memory decks may be fabricated with N+1 mask operations. The multiple memory decks may be self-aligned and certain manufacturing operations may be performed for multiple memory decks at the same time. For example, patterning a bit line direction of a first memory deck and a word line direction in a second memory deck above the first memory deck may be performed in a single masking operation, and both decks may be etched in a same subsequent etching operation. Such techniques may provide efficient fabrication which may allow for enhanced throughput, additional capacity, and higher yield for fabrication facilities relative to processing techniques in which each memory deck is processed using two or more mask and etch operations per memory deck.

A memory device includes the following items. A substrate. A bottom electrode disposed over the substrate. An insulating layer disposed over the bottom electrode, the insulating layer having a through hole defined in the insulating layer. A heater disposed in the through hole. A phase change material layer disposed over the heater. A selector layer disposed over the phase change material layer. An intermediate layer disposed over the through hole. Also, a metal layer disposed over the selector layer. The metal layer is wider than the phase change material layer.