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Many‐Body Molecular Interactions in a Memristor

Santi Prasad Rath, Damien Thompson, Sreebrata Goswami, Sreetosh Goswami

2022Advanced Materials12 citationsDOIOpen Access PDF

Abstract

Electronic transitions in molecular-circuit elements hinge on complex interactions between molecules and ions, offering a multidimensional parameter space to embed, access, and optimize material functionalities for target-specific applications. This opportunity is not cultivated in molecular memristors because their low-temperature charge transport, which is a route to decipher molecular many-body interactions, is unexplored. To address this, robust, temperature-resilient molecular memristors based on a Ru complex of an azo aromatic ligand are designed, and current-voltage sweep measurements from room temperature down to 2 K with different cooling protocols are performed. By freezing out or activating different components of supramolecular dynamics, the local Coulombic interactions between the molecules and counterions that affect the electronic transport can be controlled. Operating conditions are designed where functionalities spanning bipolar, unipolar, nonvolatile, and volatile memristors with sharp as well as gradual analog transitions are captured within a single device. A mathematical design space evolves, thereof comprising 36 tuneable parameters in which all possible steady-state functional variations in a memristor characteristic can be attainable. This enables a deterministic design route to engineer neuromorphic devices with unprecedented control over the transformation characteristics governing their functional flexibility and tunability.

Topics & Concepts

MemristorMaterials scienceNeuromorphic engineeringFlexibility (engineering)CounterionNanotechnologySupramolecular chemistryChemical physicsBioelectronicsMolecular dynamicsMolecular electronicsMoleculeIonComputer scienceElectronic engineeringPhysicsComputational chemistryChemistryBiosensorArtificial neural networkMathematicsMachine learningEngineeringQuantum mechanicsStatisticsAdvanced Memory and Neural ComputingOrganic Electronics and PhotovoltaicsConducting polymers and applications
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