Abstract: A memory cell includes a bottom electrode, a first dielectric layer, a top electrode, and a variable resistance layer. The first dielectric layer laterally surrounds the bottom electrode. The top electrode is disposed over the bottom electrode and the first dielectric layer. The variable resistance layer is sandwiched between the bottom electrode and the top electrode and between the first dielectric layer and the top electrode. The variable resistance layer exhibits a T-shape in a cross-sectional view.

Abstract: A memory cell includes a bottom electrode, a first dielectric layer, a variable resistance layer, and a top electrode. The first dielectric layer laterally surrounds the bottom electrode. A top surface of the bottom electrode is located at a level height lower than that of a top surface of the first dielectric layer. The variable resistance layer is disposed on the bottom electrode and the first dielectric layer. The variable resistance layer contacts the top surface of the bottom electrode and the top surface of the first dielectric layer. The top electrode is disposed on the variable resistance layer.

Abstract: A memory cell includes a bottom electrode, a first dielectric layer, a variable resistance layer, and a top electrode. The first dielectric layer laterally surrounds the bottom electrode. A top surface of the bottom electrode is located at a level height lower than that of a top surface of the first dielectric layer. The variable resistance layer is disposed on the bottom electrode and the first dielectric layer. The variable resistance layer contacts the top surface of the bottom electrode and the top surface of the first dielectric layer. The top electrode is disposed on the variable resistance layer.

Abstract: A memory cell includes a bottom electrode, a storage element layer, a first buffer layer, and a top electrode. The storage element layer is disposed over the bottom electrode. The first buffer layer is interposed between the storage element layer and the bottom electrode, where a thermal conductivity of the first buffer layer is less than a thermal conductivity of the storage element layer. The top electrode is disposed over the storage element layer, where the storage element layer is disposed between the top electrode and the first buffer layer.

Abstract: A memory cell includes a dielectric structure, a storage element structure, and a top electrode. The storage element structure is disposed in the dielectric structure, and the storage element structure includes a first portion and a second portion. The first portion includes a first side and a second side opposite to the first side, where a width of the first side is less than a width of the second side. The second portion is connected to the second side of the first portion, where a width of the second portion is greater than the width of the first side. The top electrode is disposed on the storage element structure, where the second portion is disposed between the first portion and the top electrode.

Abstract: A memory device includes a conductive wire, a first 2-D material layer, a phase change element, and a top electrode. The first 2-D material layer is over the conductive wire. The phase change element extends along a surface of the first 2-D material layer distal to the conductive layer. The top electrode is over the phase change element.

Abstract: A memory device includes a conductive wire, a first 2-D material layer, a phase change element, and a top electrode. The first 2-D material layer is over the conductive wire. The phase change element extends along a surface of the first 2-D material layer distal to the conductive layer. The top electrode is over the phase change element.

Abstract: A testkey design pattern includes a least one conductive contact, at least one conductive line of a first width vertically and electrically connected to the conductive contact, and at least one pair of source and drain respectively directly connected to each side of the conductive line. The pair of source and drain and part of the conductive line of a first length directly connected to the source and drain form an electronic device. The testkey design patterns are advantageous in measuring capacitance with less error and for better gate oxide thickness extraction.

Abstract: A testkey design pattern includes a least one conductive contact, at least one conductive line of a first width vertically and electrically connected to the conductive contact, and at least one pair of source and drain respectively directly connected to each side of the conductive line. The pair of source and drain and part of the conductive line of a first length directly connected to the source and drain form an electronic device. The testkey design patterns are advantageous in measuring capacitance with less error and for better gate oxide thickness extraction.

Abstract: A semiconductor structure and a method of fabricating the same are provided. A substrate having a metal-oxide-semiconductor transistor is provided. The metal-oxide-semiconductor transistor includes a gate, a source/drain extended region, a first spacer, a liner, a source/drain and a metal silicide layer. A portion of the first spacer is removed to form a second spacer by performing an etching process. A contact etching stop layer is formed over the substrate.