Atomistic Origins of Conductance Switching in an E-Cu0.9V2O5 Neuromorphic Single Crystal Oscillator

John Ponis, Nicholas Jerla, George Agbeworvi, Saul Perez-Beltran, Nitin Kumar, Kenna Ashen, Jialu Li, Edrick Wang, Michelle Smeaton, Fatme Jardali, Sarbajeet Chakraborty, Patrick Shamberger, Katherine Jungjohann, Conan Weiland, Cherno Jaye, Lu Ma, Daniel Fischer, Jinghua Guo, G. Sambandamurthy, Xiaofeng QianSarbajit Banerjee

Research output: Contribution to journalArticlepeer-review

Abstract

Building artificial neurons and synapses is key to achieving the promise of energy efficiency and acceleration envisioned for brain-inspired information processing. Emulating the spiking behavior of biological neurons in physical materials requires precise programming of conductance nonlinearities. Strong correlated solid-state compounds exhibit pronounced nonlinearities such as metal-insulator transitions arising from dynamic electron-electron and electron-lattice interactions. However, a detailed understanding of atomic rearrangements and their implications for electronic structure remains obscure. In this work, we unveil discontinuous conductance switching from an antiferromagnetic insulator to a paramagnetic metal in ..epsilon..-Cu0.9V2O5. Distinctively, fashioning nonlinear dynamical oscillators from entire millimeter-sized crystals allows us to map the structural transformations underpinning conductance switching at an atomistic scale using single-crystal X-ray diffraction. We observe superlattice ordering of Cu ions between [V4O10] layers at low temperatures, a direct result of interchain Cu-ion migration and intrachain reorganization. The resulting charge and spin ordering along the vanadium oxide framework stabilizes an insulating state. Using X-ray absorption and emission spectroscopies, assigned with the aid of electronic structure calculations and measurements of partially and completely decuprated samples, we find that Cu 3d and V 3d orbitals are closely overlapped near the Fermi level. The filling and overlap of these states, specifically the narrowing/broadening of V 3dxy states near the Fermi level, mediate conductance switching upon Cu-ion rearrangement. Understanding the mechanisms of conductance nonlinearities in terms of ion motion along specific trajectories can enable the atomistic design of neuromorphic active elements through strategies such as cointercalation and site-selective modification.
Original languageAmerican English
Pages (from-to)34536-34550
Number of pages15
JournalJournal of the American Chemical Society
Volume146
Issue number50
DOIs
StatePublished - 2024

NREL Publication Number

  • NREL/JA-5K00-92551

Keywords

  • crystal structure
  • electrical conductivity
  • electrical properties
  • ions
  • oscillation

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