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Trapped-ion quantum simulation of electron transfer models with tunable dissipation

Visal So, Midhuna Duraisamy Suganthi, Anup Menon, Mingjian Zhu, Roman Zhuravel, Han Pu, Peter G. Wolynes, José N. Onuchic, Guido Pagano

2024Science Advances23 citationsDOIOpen Access PDF

Abstract

Electron transfer is at the heart of many fundamental physical, chemical, and biochemical processes essential for life. The exact simulation of these reactions is often hindered by the large number of degrees of freedom and by the essential role of quantum effects. Here, we experimentally simulate a paradigmatic model of molecular electron transfer using a multispecies trapped-ion crystal, where the donor-acceptor gap, the electronic and vibronic couplings, and the bath relaxation dynamics can all be controlled independently. By manipulating both the ground-state and optical qubits, we observe the real-time dynamics of the spin excitation, measuring the transfer rate in several regimes of adiabaticity and relaxation dynamics. Our results provide a testing ground for increasingly rich models of molecular excitation transfer processes that are relevant for molecular electronics and light-harvesting systems.

Topics & Concepts

Relaxation (psychology)ExcitationElectron transferChemical physicsElectronDegrees of freedom (physics and chemistry)IonPhysicsMolecular dynamicsDissipationQuantumAtomic physicsQubitChemistryMaterials scienceQuantum mechanicsPhysical chemistrySocial psychologyPsychologySpectroscopy and Quantum Chemical StudiesPhotochemistry and Electron Transfer StudiesMolecular Junctions and Nanostructures
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