Transverse barrier formation by electrical triggering of a metal-to-insulator transition

Salev, Pavel; Fratino, Lorenzo; Sasaki, Dayne; Berkoun, Rani; Valle, Javier del; Kalcheim, Yoav; Takamura, Yayoi; Rozenberg, M. J.; Schuller, Iván K.

doi:10.1038/s41467-021-25802-1

Cited by 19 publications

(7 citation statements)

References 85 publications

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“…The current-induced Joule heating-triggered resistive switching that our experiments demonstrate is unlike i) the widely studied Mott insulators that transform to a metallic state from an insulating state by forming a conducting filament parallel to the current flow or ii) LSMO films on well-ordered substrates, such as STO, where the switch from a metallic to an insulating state happens by the formation of a transverse barrier perpendicular to the current flow (Salev et al, 2021). By utilizing a substrate possessing twin domains, we are able to build a complex resistive structure based on the electronic phase transition.…”

Section: Discussioncontrasting

confidence: 52%

“…In LSMO, for example, it has been shown that oxygen vacancy-driven resistive phase transitions occur and are accompanied by structural transformations from a perovskite to a brownmillerite phase (Brockman et al, 2014). Volatile resistive switching, on the other hand, utilizes the strong coupling between electronic and magnetic phases (Salev et al, 2021) and does not involve structural phase transitions (See Supplementary Figure S3 and Supplementary Figure S8).…”

Section: Discussionmentioning

confidence: 99%

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Morphology control of volatile resistive switching in La0.67Sr0.33MnO3 thin films on LaAlO3 (001)

Jaman

Goossens²,

Rijn³

et al. 2023

Front. Nanotechnol.

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The development of in-memory computing hardware components based on different types of resistive materials is an active research area. These materials usually exhibit analog memory states originating from a wide range of physical mechanisms and offer rich prospects for their integration in artificial neural networks. The resistive states are classified as either non-volatile or volatile, and switching occurs when the material properties are triggered by an external stimulus such as temperature, current, voltage, or electric field. The non-volatile resistance state change is typically achieved by the switching layer’s local redox reaction that involves both electronic and ionic movement. In contrast, a volatile change in the resistance state arises due to the transition of the switching layer from an insulator to a metal. Here, we demonstrate volatile resistive switching in twinned LaAlO3 onto which strained thin films of La0.67Sr0.33MnO3 (LSMO) are deposited. An electric current induces phase transition that triggers resistive switching, close to the competing phase transition temperature in LSMO, enabled by the strong correlation between the electronic and magnetic ground states, intrinsic to such materials. This phase transition, characterized by an abrupt resistance change, is typical of a metallic to insulating behavior, due to Joule heating, and manifested as a sharp increase in the voltage with accompanying hysteresis. Our results show that such Joule heating-induced hysteretic resistive switching exhibits different profiles that depend on the substrate texture along the current path, providing an interesting direction toward new multifunctional in-memory computing devices.

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Section: Discussioncontrasting

confidence: 52%

Section: Discussionmentioning

confidence: 99%

Morphology control of volatile resistive switching in La0.67Sr0.33MnO3 thin films on LaAlO3 (001)

Jaman

Goossens²,

Rijn³

et al. 2023

Front. Nanotechnol.

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“…However, recently, thermal effects have been used to improve bioinspired features of a device, for example, by using a heater to develop leaky integrate-and-fire in a VO 2 -based nanodevice; thermally induced transverse insulating barrier in La 0.7 Sr 0.3 MnO 3 devices; [192] and threshold switching in niobium oxide. [170,193] Further, energy-efficient implementation based on Mott-neuron has also been achieved.…”

Section: Devicesmentioning

confidence: 99%

Thermal Management in Neuromorphic Materials, Devices, and Networks

2023

Self Cite

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Machine learning has experienced unprecedented growth in recent years, often referred to as an “artificial intelligence revolution.” Biological systems inspire the fundamental approach for this new computing paradigm: using neural networks to classify large amounts of data into sorting categories. Current machine‐learning schemes implement simulated neurons and synapses on standard computers based on a von Neumann architecture. This approach is inefficient in energy consumption, and thermal management, motivating the search for hardware‐based systems that imitate the brain. Here, the present state of thermal management of neuromorphic computing technology and the challenges and opportunities of the energy‐efficient implementation of neuromorphic devices are considered. The main features of brain‐inspired computing and quantum materials for implementing neuromorphic devices are briefly described, the brain criticality and resistive switching‐based neuromorphic devices are discussed, the energy and electrical considerations for spiking‐based computation are presented, the fundamental features of the brain's thermal regulation are addressed, the physical mechanisms for thermal management and thermoelectric control of materials and neuromorphic devices are analyzed, and challenges and new avenues for implementing energy‐efficient computing are described.

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“…[ 9–13 ] In previous studies, dynamics analysis and performance characterization of the metal–insulator transition have been conducted by fabricating two‐terminal electrodes on a material and inducing the transition via electric field application or current injection. Using the resistance changes under fields as a probe of the formation of the metallic phase, the dynamics and speed of the transition have been investigated for a variety of strongly correlated materials, including vanadium oxides (VO 2 , V 2 O 3 , and V 3 O 5 ), [ 5–7,9–11,13–15 ] metal chalcogenides (AM 4 X 8 (A = Ga and Ge, M = V, Nb, and Ta, X = S and Se), [ 3,4,8,16–19 ] Ni(S,Se) 2 , [ 19 ] and 1T‐TaS 2 [ 20,21 ] ), and rare‐earth perovskite manganites [ 22 ] and nickelates, [ 12 ] and high‐speed resistive switching with a switching time down to <100 ns has been demonstrated in some materials. [ 6,11,12,17,20 ]…”

Section: Introductionmentioning

confidence: 99%

“…[9][10][11][12][13] In previous studies, dynamics analysis and performance characterization of the metal-insulator transition have been conducted by fabricating two-terminal electrodes on a material and inducing the transition via electric field application or current injection. Using the resistance changes under fields as a probe of the formation of the metallic phase, the dynamics and speed of the transition have been investigated for a variety of strongly correlated materials, including vanadium oxides (VO 2 , V 2 O 3 , and V 3 O 5 ), [5][6][7][9][10][11][13][14][15] metal chalcogenides (AM 4 X 8 (A = Ga and Ge, M = V, Nb, and Ta, X = S and Se), [3,4,8,[16][17][18][19] Ni(S,Se) 2 , [19] and 1T-TaS 2 [20,21] ), and rare-earth perovskite manganites [22] and nickelates, [12] and high-speed resistive switching with a switching time down to <100 ns has been demonstrated in some materials. [6,11,12,17,20] Recent investigations have indicated that the electrically driven resistive switching in the strongly correlated materials is generally produced by the increase in the internal temperature due to Joule heating, and temperature-driven metal-insulator transitions that are the same as those induced by temperature In Mott-type resistive switching phenomena, which are based on the metalinsulator transition in strongly correlated materials, the presence of an abrupt temperature-driven transition in the material is considered essential for achieving high-speed and large-resistance-ratio switching.…”

mentioning

confidence: 99%

Dynamics of an Electrically Driven Phase Transition in Ca₂RuO₄ Thin Films: Nonequilibrium High‐Speed Resistive Switching in the Absence of an Abrupt Thermal Transition

Tsubaki

Tsurumaki‐Fukuchi

Katase

et al. 2023

Adv Elect Materials

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In Mott‐type resistive switching phenomena, which are based on the metal–insulator transition in strongly correlated materials, the presence of an abrupt temperature‐driven transition in the material is considered essential for achieving high‐speed and large‐resistance‐ratio switching. However, this means that the freedom of material/device design in applications is significantly reduced for this type of switching by the strict requirement of transition abruptness. Here, high‐speed, abrupt resistive switching with a switching time of 140 ns is demonstrated in epitaxial films of Ca2RuO4/LaAlO3 (001), which is a material with a nonthermal metal–insulator transition driven by current, despite the complete absence of an abrupt thermal transition in the resistivity–temperature characteristics. Highly smooth negative‐differential‐resistance behavior, very high cycling stability, and an endurance over 106 cycles are also demonstrated in the current–voltage and current–time characteristics, which confirm the nonstochastic nature of the abrupt switching. These results suggest that strict control of the resistivity–temperature characteristics is not necessarily required in a material with a nonthermal‐type metal–insulator transition to obtain high‐speed resistive switching because of the independence of the dynamics from those of the thermal transition, and this phenomenon potentially has important advantages in resistive switching applications.

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Transverse barrier formation by electrical triggering of a metal-to-insulator transition

Cited by 19 publications

References 85 publications

Morphology control of volatile resistive switching in La0.67Sr0.33MnO3 thin films on LaAlO3 (001)

Morphology control of volatile resistive switching in La0.67Sr0.33MnO3 thin films on LaAlO3 (001)

Thermal Management in Neuromorphic Materials, Devices, and Networks

Dynamics of an Electrically Driven Phase Transition in Ca₂RuO₄ Thin Films: Nonequilibrium High‐Speed Resistive Switching in the Absence of an Abrupt Thermal Transition

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Transverse barrier formation by electrical triggering of a metal-to-insulator transition

Cited by 19 publications

References 85 publications

Morphology control of volatile resistive switching in La0.67Sr0.33MnO3 thin films on LaAlO3 (001)

Morphology control of volatile resistive switching in La0.67Sr0.33MnO3 thin films on LaAlO3 (001)

Thermal Management in Neuromorphic Materials, Devices, and Networks

Dynamics of an Electrically Driven Phase Transition in Ca2RuO4 Thin Films: Nonequilibrium High‐Speed Resistive Switching in the Absence of an Abrupt Thermal Transition

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Product

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Dynamics of an Electrically Driven Phase Transition in Ca₂RuO₄ Thin Films: Nonequilibrium High‐Speed Resistive Switching in the Absence of an Abrupt Thermal Transition