Electric-pulse-induced reversible resistance change effect in magnetoresistive films

Liu, Shangqing; Wu, N. J.; Ignatiev, A.

doi:10.1063/1.126464

Cited by 854 publications

(513 citation statements)

References 13 publications

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“…Tiny changes in the electronic structure or band filling at electrode/oxide interfaces can change the total resistance of memory cells by decades 23 . The process of electrical injection/rejection of oxygen ions, which should induce a change in the band filling, is considered to be one of the plausible origins of the gigantic electrical resistance switching widely observed for transition-metal oxides, including the example of the CMR manganite, which is still at the early stages of research 24 . The ReRAM has been industrialized as a storage-class memory that is between high-speed and low-density DRAM (Dynamic RAM) and low-speed and high-density storage such as hard disc drives or solid-state drives based on flash memory.…”

Section: Mottronicsmentioning

confidence: 99%

Emergent functions of quantum materials

2017

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Materials can harbour quantum many-body systems, most typically in the form of strongly correlated electrons in solids, that lead to novel and remarkable functions thanks to emergence-collective behaviours that arise from strong interactions among the elements. These include the Mott transition, high-temperature superconductivity, topological superconductivity, colossal magnetoresistance, giant magnetoelectric e ect, and topological insulators. These phenomena will probably be crucial for developing the next-generation quantum technologies that will meet the urgent technological demands for achieving a sustainable and safe society. Dissipationless electronics using topological currents and quantum spins, energy harvesting such as photovoltaics and thermoelectrics, and secure quantum computing and communication are the three major fields of applications working towards this goal. Here, we review the basic principles and the current status of the emergent phenomena and functions in materials from the viewpoint of strong correlation and topology.E mergence is a concept developed for many-body systems, indicating the properties, phenomena, and functions that never appear in the individual elements but are realized only when a huge number of elements get together 1 . Inside materials, emergent phenomena are often seen due to the interaction of electronic states; with recent developments on electronic states in solids schematically summarized in Fig. 1a. Electrons in solids have several degrees of freedom: charge, spin and orbital, and are characterized by the topological nature determined by the atomic potential on the crystal lattice structure, as schematically shown in Fig. 1b. These five attributes are coupled together and determine the overall responses to stimuli, which appear as materials' electrical, magnetic, optical, thermal, and mechanical properties.These collective electrons demonstrate various macroscopic quantum phenomena, the representative example of which is superconductivity. One of the big challenges in condensed matter physics is to increase the temperature (T c ) at which superconductivity can be observed to above room temperature. However, there are many other macroscopic quantum phenomena that are already observable above room temperature. One is magnetism (by the Bohr-van Leeuwen theorem), and the other is ferroelectricity 2,3 . Remarkably, there are common features of these three macroscopic quantum phenomena: the order parameter, which is of quantum origin, behaves as a classical quantity, and the quantum topology plays a crucial role.The topological nature of the electronic states is the key concept in the most recent developments in understanding quantum materials. The quantum Hall effect, topological insulators, and topological superconductors are all characterized by nontrivial topologies in Hilbert space. The Berry phase, which describes the connection and curvature of the subspace of Hilbert space, plays the central role in the unified principle to describe this topological nature 4 . ...

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Section: Mottronicsmentioning

confidence: 99%

Emergent functions of quantum materials

2017

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“…Therefore, the primary requirement for RRAM is to develop a material that possesses resistive switching effect. To date, a number of materials have been found to have resistive switching behavior, for example, ferromagnetic oxide (Pr 1−x Ca x MnO 3 ), doped perovskite oxide (SrZrO 3 ), and binary transition metal oxide (TiO 2 , NiO, ZnO, and Cu 2 O) [1,2,4,6,[8][9][10][11]. Among these materials, only the transition metal oxides are transparent to the visible light due to their large optical band gap.…”

Section: Introductionmentioning

confidence: 99%

“…Resistive switching random access memory (RRAM) has attracted enormous interests, due to its simple structure and compatibility with complementary metal oxide semiconductor technology [1][2][3][4][5]. In comparable with the traditional nonvolatile memories (flash), RRAM exhibits unique advantages including much faster writing rate, smaller bit cell size, and lower operating voltages.…”

Section: Introductionmentioning

confidence: 99%

Enhancement of Resistance Switching in Electrodeposited Co-ZnO Films

Chu

Younis

2012

ISRN Nanotechnology

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High quality Co-doped ZnO films were prepared with electrodeposition. The correlation among the surface morphology, lattice structure, Co-dopant distribution, and resistance switching properties of the as-deposited films were investigated. It is found that resistance switching behaviour could be manipulated by controlling the composition of Co in the ZnO films. The significant enhancement of resistance switching was achieved with 5 at% Co doping in the films, and the possible switching mechanism was also discussed.

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“…Although there had been many prior reports of anomalous hysteretic behavior in the current-voltage (I-V) characteristics of metal/dielectric/metal systems, the connection to memristive dynamics was not made. In part, this was caused by the fact that most of the previous devices that had been built and tested also possessed some very strong nonlinear electronic transport property, [5][6][7][8][9][10][11][12][13] such as tunneling or rectification, that masked the memristive behavior of these systems. Here, we demonstrate that intentionally combining these two properties that are now associated with metal-semiconductor interfaces, namely memristive switching and nonlinear Schottky-like rectification, enables us to build a family of reconfigurable electronic devices [14] with interesting and useful properties for switching, memory, and logic.…”

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confidence: 99%

A Family of Electronically Reconfigurable Nanodevices

et al. 2009

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AFM image of 17 nanodevices with a zoom‐in cartoon schematically shows an individual crosspoint device consisting of two Pt metal electrodes separated by a TiO2 bi‐layer memristive material. By applying an electric field across the memristive material, oxygen vacancies can drift up and down, leading to four current‐transport end‐states. The switching between these end‐states results in a family of nanodevices.

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Electric-pulse-induced reversible resistance change effect in magnetoresistive films

Cited by 854 publications

References 13 publications

Emergent functions of quantum materials

Emergent functions of quantum materials

Enhancement of Resistance Switching in Electrodeposited Co-ZnO Films

A Family of Electronically Reconfigurable Nanodevices

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