Meng Wang scite author profile

Multistate resistive switching device emerges as a promising electronic unit for energy-efficient neuromorphic computing. Electric-field induced topotactic phase transition with ionic evolution represents an important pathway for this purpose, which, however, faces significant challenges in device scaling. This work demonstrates a convenient scanning-probe-induced proton evolution within WO3, driving a reversible insulator-to-metal transition (IMT) at nanoscale. Specifically, the Pt-coated scanning probe serves as an efficient hydrogen catalysis probe, leading to a hydrogen spillover across the nano junction between the probe and sample surface. A positively biased voltage drives protons into the sample, while a negative voltage extracts protons out, giving rise to a reversible manipulation on hydrogenation-induced electron doping, accompanied by a dramatic resistive switching. The precise control of the scanning probe offers the opportunity to manipulate the local conductivity at nanoscale, which is further visualized through a printed portrait encoded by local conductivity. Notably, multistate resistive switching is successfully demonstrated via successive set and reset processes. Our work highlights the probe-induced hydrogen evolution as a new direction to engineer memristor at nanoscale.

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Magnetic field control of insulator-metal crossover in cobaltite films via thermally activated percolation

Wang

Matsuura²,

Nakamura³

et al. 2022

Phys. Rev. B

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Meng Wang

Enhanced low-temperature proton conductivity in hydrogen-intercalated brownmillerite oxide

Manipulating the insulator–metal transition through tip-induced hydrogenation

Nanoscale multistate resistive switching in WO3 through scanning probe induced proton evolution

Magnetic field control of insulator-metal crossover in cobaltite films via thermally activated percolation

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