Abstract: A resistive switching non-volatile memory element is disclosed comprising a resistive switching metal-oxide layer sandwiched between and in contact with a top electrode and a bottom electrode, the resistive switching metal oxide layer having a substantial isotropic non-stoichiometric metal-to-oxygen ratio. For example, the memory element may comprise a nickel oxide resistive switching layer sandwiched between and in contact with a nickel top electrode and a nickel bottom electrode whereby the ratio oxygen-to-nickel of the nickel oxide layer is between 0 and 0.85.

Abstract: A method of producing a multilayer structure is provided, wherein the method comprises forming a phase change material layer onto a substrate, forming a protective layer, forming a further layer on the protective layer, patterning the further layer in an first patterning step, patterning the protective layer and the phase change material layer by a second patterning step. In particular, the first patterning step may be an etching step using chemical etchants. Moreover, electrodes may be formed on the substrate before the phase change material layer is formed, e.g. the electrodes may be formed on one level, e.g. may form a planar structure and may not form a vertically structure.

Abstract: A phase-change-memory cell is provided which comprises two insulated regions formed in a first phase-change material connected by a region formed in a second phase-change material. The crystallization temperature of the second phase-change material is below the crystallization temperature of the first phase-change material. By locally changing the material properties using a second PCM material, which switches phase at a lower temperature, a localized “hot spot” is obtained.

Abstract: The present disclosure is related to non-volatile memory devices comprising a reversible resistivity-switching layer used for storing data. The resistivity of this layer can be varied between at least two stable resistivity states such that at least one bit can be stored therein. In particular this resistivity-switching layer is a metal oxide or a metal nitride. A resistivity-switching non-volatile memory element includes a resistivity-switching metal-oxide layer sandwiched between a top electrode and a bottom electrode. The resistivity-switching metal-oxide layer has a gradient of oxygen over its thickness. The gradient is formed in a thermal oxidation step. Set and reset voltages can be tuned by using different oxygen gradients.

Abstract: A resistive switching non-volatile memory element is disclosed comprising a resistive switching metal-oxide layer sandwiched between and in contact with a top electrode and a bottom electrode, the resistive switching metal oxide layer having a substantial isotropic non-stoichiometric metal-to-oxygen ratio. For example, the memory element may comprise a nickel oxide resistive switching layer sandwiched between and in contact with a nickel top electrode and a nickel bottom electrode whereby the ratio oxygen-to-nickel of the nickel oxide layer is between 0 and 0.85.

Abstract: A method of producing a multilayer structure is provided, wherein the method comprises forming a phase change material layer onto a substrate, forming a protective layer, forming a further layer on the protective layer, patterning the further layer in an first 5 patterning step, patterning the protective layer and the phase change material layer by a second patterning step. In particular, the first patterning step may be an etching step using chemical etchants. Moreover, electrodes may be formed on the substrate before the phase change material layer is formed, e.g. the electrodes may be formed on one level, e.g. may forma planar structure and may not form a vertically structure.

Abstract: A memory device comprises an array of memory cells for storing data and a voltage application unit for applying voltages to the cells for writing data to the cells. Each memory cell has a first layer comprising copper in contact with a second layer comprising a chalcogenide material. The voltage application unit is arranged to write data by switching each cell between a first resistance state and a second, lower, resistance state. The voltage application unit is arranged to switch a cell to the first resistance state by applying a potential difference across the first and second layers such that the potential at the first layer is higher than the potential at the second layer by 0.5 volts or less. The voltage application unit is arranged to switch a cell to the second resistance state by applying a potential difference across the first and second layers such that the potential at the second layer is higher than the potential at the first layer by 0.5 volts or less.

Abstract: The present disclosure is related to non-volatile memory devices comprising a reversible resistivity-switching layer used for storing data. The resistivity of this layer can be varied between at least two stable resistivity states such that at least one bit can be stored therein. In particular this resistivity-switching layer is a metal oxide or a metal nitride. A resistivity-switching non-volatile memory element includes a resistivity-switching metal-oxide layer sandwiched between a top electrode and a bottom electrode. The resistivity-switching metal-oxide layer has a gradient of oxygen over its thickness. The gradient is formed in a thermal oxidation step. Set and reset voltages can be tuned by using different oxygen gradients.

Abstract: The present invention is related to the realization of a simplified bottom electrode stack for ferroelectric memory cells. More particularly, the invention is related to ferroelectric memory cells wherein the ferroelectric capacitor is positioned directly on top of a contact plug. The bottom electrode stack is prepared by depositing a ferroelectric film atop an Ir or Ru metal electrode layer, then annealing the ferroelectric layer in an oxygen ambient wherein the partial pressure of oxygen is controlled at a level sufficient to oxidize the ferroelectric layer but not at a level sufficient to oxidize the metal electrode layer.

Abstract: The present invention is related to the realization of a simplified bottom electrode stack for ferroelectric memory cells. More particularly, the invention is related to ferroelectric memory cells wherein the ferroelectric capacitor is positioned directly on top of a contact plug.

Abstract: The present invention is related to the realization of a simplified bottom electrode stack for ferroelectric memory cells. More particularly, the invention is related to ferroelectric memory cells wherein the ferroelectric capacitor is positioned directly on top of a contact plug.

Abstract: The present invention is related to the realization of a simplified bottom electrode stack for ferroelectric memory cells. More particularly, the invention is related to ferroelectric memory cells wherein the ferroelectric capacitor is positioned directly on top of a contact plug.