Abstract: A method of forming a memory device, such as a PCRAM, including selecting a chalcogenide glass backbone material for a resistance variable memory function and devices formed using such a method.

Abstract: A method of forming a memory device, such as a PCRAM, including selecting a chalcogenide glass backbone material for a resistance variable memory function and devices formed using such a method.

Abstract: Non-volatile memory devices with two stacked layers of chalcogenide materials comprising the active memory device have been investigated for their potential as phase-change memories. The devices tested included GeTe/SnTe, Ge2Se3/SnTe, and Ge2Se3/SnSe stacks. All devices exhibited resistance switching behavior. The polarity of the applied voltage with respect to the SnTe or SnSe layer was critical to the memory switching properties, due to the electric field induced movement of either Sn or Te into the Ge-chalcogenide layer. One embodiment of the invention is a device comprising a stack of chalcogenide-containing layers which exhibit phase-change switching only after a reverse polarity voltage potential is applied across the stack causing ion movement into an adjacent layer and thus “activating” the device to act as a phase-change random access memory device or a reconfigurable electronics device when the applied voltage potential is returned to the normal polarity.

Abstract: A circuit with a capacitive device is disclosed. The circuit may comprise a capacitive device connected between a first conductor and a second conductor. The capacitive device may comprise a first electrode connected to the first conductor and a second electrode being connected to the second conductor. A chalcogenide layer may be connected to the first electrode and to a metal chalcogenide layer.

Abstract: The invention is related to methods and apparatus for providing a resistance variable memory element with improved data retention and switching characteristics. According to one embodiment of the invention, a resistance variable memory element is provided having at least one silver-selenide layer in between two glass layers, wherein at least one of the glass layers is a chalcogenide glass, preferably having a GexSe100?x composition. According to another embodiment of the invention, a resistance variable memory element is provided having at least one silver-selenide layer in between chalcogenide glass layers and further having a silver layer above at least one of said chalcogenide glass layers and a conductive adhesion layer above said silver layer.

Abstract: A phase change memory element and method of forming the same. The memory element includes first and second electrodes. A first layer of phase change material is between the first and second electrodes. A second layer including a metal-chalcogenide material is also between the first and second electrodes and is one of a phase change material and a conductive material. An insulating layer is between the first and second layers. There is at least one opening in the insulating layer providing contact between the first and second layers.

Abstract: The invention relates to the use of chalcogenide devices exhibiting negative differential resistance in integrated circuits as programmable variable resistor components. The present invention is a continuously variable integrated analog resistor made of a chalcogenide material, such as a GeSeAg alloy. Continuously variable resistor states are obtained in the material via application of an electrical pulse to it. The pulse sequence, duration and applied potential determine the value of the resistance state obtained.

Abstract: A chalcogenide-based programmable conductor memory device and method of forming the device, wherein a nanoparticle is provided between an electrode and a chalcogenide glass region. The method of forming the nanoparticle utilizes a template over the electrode or random deposition of the nanoparticle.

Abstract: The invention is related to methods and apparatus for providing a resistance variable memory element with improved data retention and switching characteristics. According to an embodiment of the invention a resistance variable memory element is provided having at least one silver-selenide layer in between glass layers, wherein at least one of the glass layers is a chalcogenide glass, preferably having a GexSe100-x composition.

Abstract: Methods and apparatus for providing a memory device that can be programmed a limited number of times. According to exemplary embodiments, a memory device and its method of formation provide a first electrode, a second electrode and a layer of a chalcogenide or germanium comprising material between the first electrode and the second electrode. The memory device further includes a tin-chalcogenide layer between the chalcogenide or germanium comprising material layer and the second electrode.

Abstract: A chalcogenide-based programmable conductor memory device and method of forming the device, wherein a nanoparticle is provided between an electrode and a chalcogenide glass region. The method of forming the nanoparticle utilizes a template over the electrode or random deposition of the nanoparticle.

Abstract: The invention is related to methods and apparatus for providing a resistance variable memory element with improved data retention and switching characteristics. According to an embodiment of the invention a resistance variable memory element is provided having at least one silver-selenide layer in between glass layers, wherein at least one of the glass layers is a chalcogenide glass, preferably having a GexSe100-x composition.

Abstract: A memory device comprising a first electrode, a second electrode, metal-chalcogenide material between the first and second electrodes and chalcogenide glass between the first and second electrodes. The chalcogenide glass comprises a material with the chemical formula AxB100-x, wherein A is a non-chalcogenide component and B is a chalcogenide component, and A has a bonding affinity for B relative to homopolar bonds of A. The memory device further comprises a conducting channel in the chalcogenide glass comprising bonds formed between A and a component of the metal chalcogenide material.

Abstract: A circuit with a capacitive device is disclosed. The circuit may comprise a capacitive device connected between a first conductor and a second conductor. The capacitive device may comprise a first electrode connected to the first conductor and a second electrode being connected to the second conductor. A chalcogenide layer may be connected to the first electrode and to a metal chalcogenide layer.

Abstract: Non-volatile memory devices with two stacked layers of chalcogenide materials comprising the active memory device have been investigated for their potential as phase-change memories. The devices tested included GeTe/SnTe, Ge2Se3/SnTe, and Ge2Se3/SnSe stacks. All devices exhibited resistance switching behavior. The polarity of the applied voltage with respect to the SnTe or SnSe layer was critical to the memory switching properties, due to the electric field induced movement of either Sn or Te into the Ge-chalcogenide layer. One embodiment of the invention is a device comprising a stack of chalcogenide-containing layers which exhibit phase-change switching only after a reverse polarity voltage potential is applied across the stack causing ion movement into an adjacent layer and thus “activating” the device to act as a phase-change random access memory device or a reconfigurable electronics device when the applied voltage potential is returned to the normal polarity.

Abstract: A phase change memory element and method of forming the same. The memory element includes first and second electrodes. A first layer of phase change material is between the first and second electrodes. A second layer including a metal-chalcogenide material is also between the first and second electrodes and is one of a phase change material and a conductive material. An insulating layer is between the first and second layers. There is at least one opening in the insulating layer providing contact between the first and second layers.

Abstract: A method of forming a memory device, such as a PCRAM, including selecting a chalcogenide glass backbone material for a resistance variable memory function and devices formed using such a method.

Abstract: A phase change memory element and method of forming the same. The memory element includes first and second electrodes. A first layer of phase change material is between the first and second electrodes. A second layer including a metal-chalcogenide material is also between the first and second electrodes and is one of a phase change material and a conductive material. An insulating layer is between the first and second layers. There is at least one opening in the insulating layer providing contact between the first and second layers.

Abstract: A chalcogenide-based programmable conductor memory device and method of forming the device, wherein a chalcogenide glass region is provided with a plurality of alternating tin chalcogenide and metal layers proximate thereto. The method of forming the device comprises sputtering the alternating tin chalcogenide and metal layers.

Abstract: Non-volatile memory devices with two stacked layers of chalcogenide materials comprising the active memory device have been investigated for their potential as phase change memories. The devices tested included GeTe/SnTe, Ge2Se3/SnTe, and Ge2Se3/SnSe stacks. All devices exhibited resistance switching behavior. The polarity of the applied voltage with respect to the SnTe or SnSe layer was critical to the memory switching properties, due to the electric field induced movement of either Sn or Te into the Ge-chalcogenide layer. One embodiment of the invention is a device comprising a stack of chalcogenide-containing layers which exhibit phase change switching only after a reverse polarity voltage potential is applied across the stack causing ion movement into an adjacent layer and thus “activating” the device to act as a phase change random access memory device or a reconfigurable electronics device when the applied voltage potential is returned to the normal polarity.