Abstract: A phase changeable material layer usable in a semiconductor memory device and a method of forming the same are disclosed.

Abstract: Phase change memory devices can have bottom patterns on a substrate. Line-shaped or L-shaped bottom electrodes can be formed in contact with respective bottom patterns on a substrate and to have top surfaces defined by dimensions in x and y axes directions on the substrate. The dimension along the x-axis of the top surface of the bottom electrodes has less width than a resolution limit of a photolithography process used to fabricate the phase change memory device. Phase change patterns can be formed in contact with the top surface of the bottom electrodes to have a greater width than each of the dimensions in the x and y axes directions of the top surface of the bottom electrodes and top electrodes can be formed on the phase change patterns, wherein the line shape or the L shape represents a sectional line shape or a sectional L shape of the bottom electrodes in the x-axis direction.

Abstract: Provided are a phase change memory device and a method for forming the phase change memory device. The method includes forming a phase change material layer by providing reactive radicals to a substrate. The reactive radicals may comprise precursors for a phase change material and nitrogen.

Abstract: A memory device using a phase change material and a method for forming the same are disclosed. One embodiment of a memory device includes a first insulating layer provided on a substrate and defining an opening; a first conductor including a first portion and a second portion, the first portion provided on a bottom of the opening, the second portion being continuously provided along a sidewall of the opening; a variable resistor connected to the second portion of the first conductor and provided along the sidewall of the opening; and a second conductor provided on the variable resistor.

Abstract: Methods of fabricating integrated circuit memory cells and integrated circuit memory cells are disclosed. Formation of an integrated circuit memory cell include forming a first electrode on a substrate. An insulation layer is formed on the substrate with an opening that exposes at least a portion of a first electrode. An amorphous variable resistivity material is formed on the first electrode and extends away from the first electrode along sidewalls of the opening. A crystalline variable resistivity material is formed in the opening on the amorphous variable resistivity material. A second electrode is formed on the crystalline variable resistivity material.

Abstract: A phase change memory device includes a lower electrode provided on a substrate, an interlayer insulating layer including a contact hole exposing the lower electrode, and covering the substrate, a resistant material pattern filling the contact hole, a phase change pattern interposed between the resistant material pattern and the interlayer insulating layer, and extending between the resistant material pattern and the lower electrode, wherein the resistant material pattern has a higher resistance than the phase change pattern, and an upper electrode in contact with the phase change pattern, the upper electrode being electrically connected to the lower electrode through the phase change pattern.

Abstract: The present invention provides metal precursors for low temperature deposition. The metal precursors include a metal ring compound including at least one metal as one of a plurality of elements forming a ring. Methods of forming a metal thin layer and manufacturing a phase change memory device including use of the metal precursors is also provided.

Abstract: A phase-changeable layer and a method of forming the same are disclosed. In the method, a first hydrogen gas is introduced into a reaction chamber into which a substrate is loaded at a first flow rate to form first plasma. A primary cyclic CVD process is carried out using precursors in the reaction chamber to form a lower phase-changeable layer having a first grain size on the substrate. A second hydrogen gas is introduced into the reaction chamber at a second flow rate less than the first flow rate to form second plasma. A secondary cyclic CVD process is carried out using the precursors in the reaction chamber to form an upper phase-changeable layer having a second grain size smaller than the first grain size on the substrate, thereby forming a phase-changeable layer. Thus, the phase-changeable layer may have strong adhesion strength with respect to a lower layer and good electrical characteristics.

Abstract: In one embodiment, a phase change memory device includes an insulation structure over a substrate. The insulation structure ahs an opening defined therethrough. A first layer pattern is formed on sidewalls and a bottom of the opening. A second layer pattern is formed on the first layer pattern and substantially fills the opening.

Abstract: Example embodiments may provide phase-change material layers and a method of forming a phase-change material layer and devices using the same by generating a plasma including helium and/or argon in a reaction chamber, forming a first material layer on the object by introducing a first source gas including a first material, forming a first composite material layer on the object by introducing a second source gas including a second material into the reaction chamber, forming a third material layer on the first composite material layer by introducing a third source gas including a third material, and forming a second composite material layer on the first composite material layer by introducing a fourth source gas including a fourth material. Example embodiment phase-change material layers including carbon may be more easily and/or quickly formed at lower temperatures under the helium/argon plasma environment by providing the source gases for various feeding times.

Abstract: A method includes forming a phase change material layer on a substrate using a deposition process that employs a process gas. The process gas includes a germanium source gas, and the germanium source gas includes at least one of the atomic groups “—N?C?O”, “—N?C?S”, “—N?C?Se”, “—N?C?Te”, “—N?C?Po” and “—C?N”.

Abstract: A gap filling method and a method for forming a memory device, including forming an insulating layer on a substrate, forming a gap region in the insulating layer, and repeatedly forming a phase change material layer and etching the phase change material layer to form a phase change material layer pattern in the gap region.

Abstract: A method of forming a phase change material layer includes preparing a substrate having an insulator and a conductor, loading the substrate into a process housing, injecting a deposition gas into the process housing to selectively form a phase change material layer on an exposed surface of the conductor, and unloading the substrate from the process housing, wherein a lifetime of the deposition gas in the process housing is shorter than a time the deposition gas takes to react by thermal energy.

Abstract: A method of fabricating a phase-change random-access memory (RAM) device includes forming a chalcogenide material on a substrate. A bottom contact is formed under the chalcogenide material, the bottom contact comprising TiAlN. Forming the bottom contact includes performing an atomic layer deposition (ALD) process, the ALD process including introducing an NH3 source gas into a chamber in which the ALD process is being carried out, a flow amount of the NH3 gas being such that the resulting bottom contact has a chlorine content of less than 1 at %. The bottom contact can include TiAlN having a crystallinity in terms of full-width half-maximum (FWHM) of less than about 0.65 degree.

Abstract: A phase changeable material layer usable in a semiconductor memory device and a method of forming the same are disclosed.