Fast, robust, and amplified transfer of topological edge modes on a time-varying mechanical chain
Ioannis Brouzos, Ioannis Kiorpelidis, F. Κ. Diakonos, Georgios Theocharis
Abstract
We show that it is possible to successfully, rapidly, and robustly transfer a topological vibrational edge mode across a time-varying mechanical chain. The stiffness values of the springs of the chain are arranged in an alternating staggered way such that we obtain a mechanical analog of the quantum Su-Schrieffer-Heeger model, which exhibits a nontrivial topological phase. Using optimal control methods, we are able to design control schemes for driving the stiffness parameters such that the transfer is done with high fidelity, speed, and robustness against disorder as well as energy amplification of the target edge mode.
Topics & Concepts
StiffnessRobustness (evolution)Chain (unit)FidelityTopology (electrical circuits)QuantumEnergy transferEnhanced Data Rates for GSM EvolutionHigh fidelityPhysicsMechanical systemControl theory (sociology)Robust controlMechanical energyTransfer (computing)Statistical physicsComputer scienceControl (management)Quantum mechanicsMathematicsAcousticsMolecular physicsArtificial intelligenceChemistryThermodynamicsParallel computingBiochemistryTelecommunicationsCombinatoricsGeneNonlinear systemPower (physics)Topological Materials and PhenomenaMechanical and Optical ResonatorsNonlinear Photonic Systems