Abstract: A phase change material layer includes antimony (Sb) and at least one of indium (In) and gallium (Ga). A phase change memory device includes a storage node including a phase change material layer and a switching device connected to the storage node. The phase change material layer includes Sb and at least one of In and Ga.

Abstract: A photodiode includes a p-type semiconductor material and an n-type chalcogenide compound. The p-type semiconductor material and the n-type chalcogenide compound form a pn-junction.

Abstract: A sensor, including a plurality of photo gate pairs on a semiconductor substrate, each of the photo gate pairs including a first photo gate and a second photo gate, a first shared floating diffusion region in the semiconductor substrate, and a plurality of first transmission transistors on the semiconductor substrate, wherein each of the plurality of first transmission transistors is adapted to transmit charges to the first shared floating diffusion region in response to a first transmission control signal, the charges being generated in the semiconductor substrate under the first photo gate of each of the plurality of photo gate pairs.

Abstract: A method includes providing packets to demodulate a modulated photon signal output from a light source, wherein each packet includes a first interval and a second interval, and providing oscillation signals respectively having different phases from one another to photogates during the first interval of each of the packets. The light source is disabled and a direct current (DC) voltage is provided to the photogates during the second interval of each of the packets.

Abstract: Insulating impurities may be uniformly distributed over an entire or partial region of the phase change material. The PRAM may include a phase change layer including the phase change material. The insulating impurity content of the phase change material may be 0.1 to 10% (inclusive) the volume of the phase change material. The insulating impurity content of the phase change material may be adjusted by controlling the power applied to a target including the insulating impurities.

Abstract: A resistive memory device includes a vertical transistor and a variable resistance layer. The vertical transistor includes a gate electrode on a surface of a substrate, a gate insulation layer extending along a sidewall of the gate electrode, and a single crystalline silicon layer on the surface of the substrate adjacent to the gate insulation layer. At least a portion of the single crystalline silicon layer defines a channel region that extends in a direction substantially perpendicular to the surface of the substrate. The variable resistance layer is provided on the single crystalline silicon layer. The variable resistance layer is electrically insulated from the gate electrode. Related devices and fabrication methods are also discussed.

Abstract: A method of measuring a resistance of a memory cell in a resistive memory device can be provided by applying a data write pulse to a selected cell of the resistive memory device, applying a resistance read pulse to the selected cell after a delay time measured from a time of applying the data write pulse, measuring a drop voltage at the cell responsive to a pulse waveform output when applying the resistance read pulse to the selected cell, measuring a total current through the cell using the drop voltage and an internal resistance of a test device coupled to the cell, and determining a resistance of the resistive memory device using the total current and a voltage of the resistance read pulse.

Abstract: In some embodiments, the present invention is directed to processes for the combination of injecting charge in a material electrochemically via non-faradaic (double-layer) charging, and retaining this charge and associated desirable properties changes when the electrolyte is removed. The present invention is also directed to compositions and applications using material property changes that are induced electrochemically by double-layer charging and retained during subsequent electrolyte removal. In some embodiments, the present invention provides reversible processes for electrochemically injecting charge into material that is not in direct contact with an electrolyte. Additionally, in some embodiments, the present invention is directed to devices and other material applications that use properties changes resulting from reversible electrochemical charge injection in the absence of an electrolyte.

Abstract: In a memory device, a transistor may be formed on a substrate, and a first electrode may be electrically connected thereto. A phase change material film may be vertically formed on the first electrode, and a second electrode may be formed on the phase change material film.

Abstract: A PRAM and a fabricating method thereof are provided. The PRAM includes a transistor and a data storage capability. The data storage capability is connected to the transistor. The data storage includes a top electrode, a bottom electrode, and a porous PCM layer. The porous PCM layer is interposed between the top electrode and the bottom electrode.

Abstract: In some embodiments, the present invention is directed to processes for the combination of injecting charge in a material electrochemically via non-faradaic (double-layer) charging, and retaining this charge and associated desirable properties changes when the electrolyte is removed. The present invention is also directed to compositions and applications using material property changes that are induced electrochemically by double-layer charging and retained during subsequent electrolyte removal. In some embodiments, the present invention provides reversible processes for electrochemically injecting charge into material that is not in direct contact with an electrolyte. Additionally, in some embodiments, the present invention is directed to devices and other material applications that use properties changes resulting from reversible electrochemical charge injection in the absence of an electrolyte.

Abstract: In some embodiments, the present invention is directed to processes for the combination of injecting charge in a material electrochemically via non-faradaic (double-layer) charging, and retaining this charge and associated desirable properties changes when the electrolyte is removed. The present invention is also directed to compositions and applications using material property changes that are induced electrochemically by double-layer charging and retained during subsequent electrolyte removal. In some embodiments, the present invention provides reversible processes for electrochemically injecting charge into material that is not in direct contact with an electrolyte. Additionally, in some embodiments, the present invention is directed to devices and other material applications that use properties changes resulting from reversible electrochemical charge injection in the absence of an electrolyte.

Abstract: In some embodiments, the present invention is directed to processes for the combination of injecting charge in a material electrochemically via non-faradaic (double-layer) charging, and retaining this charge and associated desirable properties changes when the electrolyte is removed. The present invention is also directed to compositions and applications using material property changes that are induced electrochemically by double-layer charging and retained during subsequent electrolyte removal. In some embodiments, the present invention provides reversible processes for electrochemically injecting charge into material that is not in direct contact with an electrolyte. Additionally, in some embodiments, the present invention is directed to devices and other material applications that use properties changes resulting from reversible electrochemical charge injection in the absence of an electrolyte.

Abstract: In some embodiments, the present invention is directed to processes for the combination of injecting charge in a material electrochemically via non-faradaic (double-layer) charging, and retaining this charge and associated desirable properties changes when the electrolyte is removed. The present invention is also directed to compositions and applications using material property changes that are induced electrochemically by double-layer charging and retained during subsequent electrolyte removal. In some embodiments, the present invention provides reversible processes for electrochemically injecting charge into material that is not in direct contact with an electrolyte. Additionally, in some embodiments, the present invention is directed to devices and other material applications that use properties changes resulting from reversible electrochemical charge injection in the absence of an electrolyte.

Abstract: Provided is a method of operating a phase change random access memory comprising a switching device and a storage node comprising a phase change layer. The method includes applying a reset current passing through the phase change layer from a lower portion of the phase change layer toward an upper portion of the phase change layer and being smaller than 1.6 mA to the storage node to change a portion of the phase change layer into an amorphous state. The set voltage is in an opposite direction is exemplary embodiments, and a connector is of small cross-sectional area.

Abstract: Provided are a doped phase change material and a phase change memory device including the phase change material. The phase change material, which may be doped with Se, has a higher crystallization temperature than a Ge2Sb2Te5 (GST) material. The phase change material may be InXSbYTeZSe100?(X+Y+Z). The index X of indium (In) is in the range of 25 wt %?X?60 wt %. The index Y of antimony (Sb) is in the range of 1 wt %?Y?17 wt %. The index Z of tellurium (Te) is in the range of 0 wt %<Z?75 wt %.

Abstract: Provided are a phase change material containing carbon (C), a memory device including the phase change material, and a method of operating the memory device. The phase change material contains a main compound and an additive, wherein the main compound is In—Sb—Te and the additive includes carbon (C). A content a of the carbon (C) may be 0.005?a?0.30 atomic (at) %. The additive may further contain nitrogen (N), oxygen (O), boron (B), or a transition metal. The additive may include carbide instead of the carbon (C).

Abstract: Provided is a non-volatile memory device including at least one horizontal electrode, at least one vertical electrode, at least one data storage layer and at least one reaction prevention layer. The least one vertical electrode crosses the at least one horizontal electrode. The at least one data storage layer is located in regions in which the at least one vertical electrode crosses the at least one horizontal electrode, and stores data by varying its electrical resistance. The at least one reaction prevention layer is located in the regions in which the at least one vertical electrode crosses the at least one horizontal electrode.

Abstract: Provided are phase change random access memory (PRAM) devices and methods of operating the same. The PRAM device may include a switching device, a lower electrode, a lower electrode contact layer, a phase change layer and/or an upper electrode. The lower electrode may be connected to a switching device. The lower electrode contact layer may be formed on the lower electrode. The phase change layer, which may include a bottom surface that contacts an upper surface of the lower electrode contact layer, may be formed on the lower electrode contact layer. The upper electrode may be formed on the phase change layer. The lower electrode contact layer may be formed of a material layer having an absolute value of a Seebeck coefficient higher than TiAlN. The Seebeck coefficient of the lower electrode contact layer may be negative. The material layer may have lower heat conductivity and/or approximately equivalent electrical resistance as TiAlN.

Abstract: A storage node may include a bottom electrode contact layer, a phase change layer connected to the bottom electrode contact layer, and a top electrode layer connected to the phase change layer. The bottom electrode contact layer may protrude toward the phase change layer. A phase change memory device may include a switching device and the storage node. The switching device may be connected to the bottom electrode contact layer. A method of manufacturing the storage node may include forming a via hole in an insulating interlayer, at least partially filling the via hole to form a bottom electrode contact layer, protruding the bottom electrode contact layer from the via hole, and forming a phase change layer that covers the bottom electrode contact layer. A method of manufacturing a phase change memory device may include forming the switching device on a substrate and manufacturing the storage node.