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Terahertz radiation by quantum interference of excitons in a one-dimensional Mott insulator

Tatsuya Miyamoto, Akihiro Kondo, Takeshi Inaba, Takeshi Morimoto, S You, Hiroshi Okamoto

2023Nature Communications10 citationsDOIOpen Access PDF

Abstract

Nearly monocyclic terahertz waves are used for investigating elementary excitations and for controlling electronic states in solids. They are usually generated via second-order optical nonlinearity by injecting a femtosecond laser pulse into a nonlinear optical crystal. In this framework, however, it is difficult to control phase and frequency of terahertz waves. Here, we show that in a one-dimensional Mott insulator of a nickel-bromine chain compound a terahertz wave is generated with high efficiency via strong electron modulations due to quantum interference between odd-parity and even-parity excitons produced by two-color femtosecond pulses. Using this method, one can control all of the phase, frequency, and amplitude of terahertz waves by adjusting the creation-time difference of two excitons with attosecond accuracy. This approach enables to evaluate the phase-relaxation time of excitons under strong electron correlations in Mott insulators. Moreover, phase- and frequency-controlled terahertz pulses are beneficial for coherent electronic-state controls with nearly monocyclic terahertz waves.

Topics & Concepts

Mott insulatorTerahertz radiationInterference (communication)Quantum interferenceExcitonPhysicsInsulator (electricity)QuantumRadiationCondensed matter physicsOptoelectronicsQuantum mechanicsComputer scienceTelecommunicationsChannel (broadcasting)Terahertz technology and applicationsSemiconductor Quantum Structures and DevicesStrong Light-Matter Interactions