Abstract: A variable resistance memory device includes memory cells arranged on a substrate and an insulating structure between the memory cells. Each of the memory cells includes a variable resistance pattern and a switching pattern vertically stacked on the substrate. The insulating structure includes a first insulating pattern between the memory cells, and a second insulating pattern between the first insulating pattern and each of the memory cells. The first insulating pattern includes a material different from a material of the second insulating pattern.

Abstract: Integrated circuit (IC) devices are provided. An IC device includes a substrate including an active region. The IC device includes a bit line on the substrate. The IC device includes a direct contact connected between the active region and the bit line. The IC device includes a contact plug on the substrate. Moreover, the IC device includes a boron-containing insulating pattern between the contact plug and the direct contact.

Abstract: A variable resistance memory device includes memory cells arranged on a substrate and an insulating structure between the memory cells. Each of the memory cells includes a variable resistance pattern and a switching pattern vertically stacked on the substrate. The insulating structure includes a first insulating pattern between the memory cells, and a second insulating pattern between the first insulating pattern and each of the memory cells. The first insulating pattern includes a material different from a material of the second insulating pattern.

Abstract: Integrated circuit (IC) devices are provided. An IC device includes a substrate including an active region. The IC device includes a bit line on the substrate. The IC device includes a direct contact connected between the active region and the bit line. The IC device includes a contact plug on the substrate. Moreover, the IC device includes a boron-containing insulating pattern between the contact plug and the direct contact.

Abstract: A semiconductor device may include a semiconductor substrate, a trench isolation layer on the semiconductor substrate and configured to define an active region, and a multi-liner layer on an inside wall of a trench including the trench isolation layer. The multi-liner layer may include a first liner layer on the inside wall of the trench, a second liner layer on the first liner layer, and a third liner layer on the second liner layer.

Abstract: Provided is a method of forming a semiconductor device. The method can include loading a semiconductor substrate into semiconductor equipment. A base layer can be formed on the loaded semiconductor substrate by performing a base deposition process using a base source material. A first silicon layer can be formed on the base layer to a greater thickness than the base layer by performing a first silicon deposition process using a silicon source material different from the base source material. A first nitrided silicon layer can be formed by nitriding the first silicon layer using a first nitridation process. The semiconductor substrate having the first nitrided silicon layer can be unloaded from the semiconductor equipment.

Abstract: A method of fabricating semiconductor devices may include forming a mold structure on a lower layer, the mold structure including an etch stop layer doped at a first impurity concentration, a lower mold layer doped at a second impurity concentration, and an undoped upper mold layer. The method may include forming a trench exposing the lower layer in the mold structure using dry etching, extending a width of the trench in the etch stop layer using wet etching, and forming a first conductive pattern in the extended width trench, wherein an etch rate of the etch stop layer with respect to the dry etching may be smaller than an etch rate of the lower mold layer with respect to the dry etching, and an etch rate of the etch stop layer with respect to the wet etching may be proportional to the first impurity concentration.

Abstract: Provided is a method of forming a semiconductor device. The method can include loading a semiconductor substrate into semiconductor equipment. A base layer can be formed on the loaded semiconductor substrate by performing a base deposition process using a base source material. A first silicon layer can be formed on the base layer to a greater thickness than the base layer by performing a first silicon deposition process using a silicon source material different from the base source material. A first nitrided silicon layer can be formed by nitriding the first silicon layer using a first nitridation process. The semiconductor substrate having the first nitrided silicon layer can be unloaded from the semiconductor equipment.

Abstract: A method of fabricating semiconductor devices may include forming a mold structure on a lower layer, the mold structure including an etch stop layer doped at a first impurity concentration, a lower mold layer doped at a second impurity concentration, and an undoped upper mold layer. The method may include forming a trench exposing the lower layer in the mold structure using dry etching, extending a width of the trench in the etch stop layer using wet etching, and forming a first conductive pattern in the extended width trench, wherein an etch rate of the etch stop layer with respect to the dry etching may be smaller than an etch rate of the lower mold layer with respect to the dry etching, and an etch rate of the etch stop layer with respect to the wet etching may be proportional to the first impurity concentration.

Abstract: A semiconductor device includes a semiconductor substrate having an active region. A gate trench is disposed to cross the active region. First and second source/drain regions are disposed in the active region at both sides of the gate trench. A gate electrode is disposed in the gate trench. A gate dielectric layer is disposed between the gate electrode and the active region. A stress pattern is disposed on the gate electrode and in the gate trench. The stress pattern has a lower residual stress than silicon nitride.

Abstract: In a method of forming a layer having a lower electrical resistance and a method of manufacturing a semiconductor device, a first layer may be formed on a single crystalline substrate using amorphous silicon doped with impurities. A heat treatment may be performed on the single crystalline substrate at a temperature of about 550° C. to about 600° C. to convert the first layer into a second layer including a single crystalline silicon film transformed from a lower portion of the first layer contacting the single crystalline substrate and a polysilicon film transformed from an upper portion of the first layer. The layer may be formed at a relatively low temperature by a selective epitaxial growth process, and thus degradation or damage to a semiconductor device, which may be generated in a high temperature process, may be reduced.

Abstract: In a capacitor having a semiconductor-insulator-metal (SIM) structure, an upper electrode may be formed into a multilayer structure including a polycrystalline semiconductor Group IV material. A dielectric layer may include a metal oxide, and a lower electrode may include a metal-based material. Therefore, a capacitor may have a sufficiently small equivalent oxide thickness (EOT) and/or may have improved current leakage characteristics.