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Main Authors: Ikeda, Ryohei, Murakami, Yuta, Sakai, Daiki, Miyamoto, Tatsuya, Ito, Toshimitsu, Okamoto, Hiroshi
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2508.00296
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author Ikeda, Ryohei
Murakami, Yuta
Sakai, Daiki
Miyamoto, Tatsuya
Ito, Toshimitsu
Okamoto, Hiroshi
author_facet Ikeda, Ryohei
Murakami, Yuta
Sakai, Daiki
Miyamoto, Tatsuya
Ito, Toshimitsu
Okamoto, Hiroshi
contents Solids in an intense laser field show high-harmonic generation (HHG), which can provide information on carrier dynamics and band structures in weakly correlated systems. In strongly correlated systems, a laser field can induce a transition between the various electronic phases formed by the entanglement of charge, spin, and orbital degrees of freedom via carrier generation. The HHG accompanying this process should contain information on the nonequilibrium electronic-state dynamics along the oscillating field - an aspect that remains unresolved to date. Here, we show that an intense mid-infrared (MIR) pulse induces a Mott insulator-metal transition in a one-dimensional cuprate, Sr2CuO3, the evolution of which is reflected by the spectral features of HHs. When the electric-field amplitude exceeds 6 MV/cm, carriers are efficiently generated and each harmonic frequency decreases from odd multiples of the MIR frequency. Dynamical mean-field theory indicates that these redshifts originate from a series of electronic-structure reconstructions in each electric-field cycle during the melting of the Mott-insulator state, which modifies the radiation phase from carrier recombination cycle-by-cycle. This phenomenon is negligible in rigid-band systems. This experimental-theoretical study confirms that HH spectroscopy research can potentially unravel the sub-cycle dynamics of nonequilibrium phase transitions in correlated materials.
format Preprint
id arxiv_https___arxiv_org_abs_2508_00296
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle High harmonic generation reflecting the sub-cycle evolution of the Mott transition under a mid-infrared electric field
Ikeda, Ryohei
Murakami, Yuta
Sakai, Daiki
Miyamoto, Tatsuya
Ito, Toshimitsu
Okamoto, Hiroshi
Strongly Correlated Electrons
Optics
Solids in an intense laser field show high-harmonic generation (HHG), which can provide information on carrier dynamics and band structures in weakly correlated systems. In strongly correlated systems, a laser field can induce a transition between the various electronic phases formed by the entanglement of charge, spin, and orbital degrees of freedom via carrier generation. The HHG accompanying this process should contain information on the nonequilibrium electronic-state dynamics along the oscillating field - an aspect that remains unresolved to date. Here, we show that an intense mid-infrared (MIR) pulse induces a Mott insulator-metal transition in a one-dimensional cuprate, Sr2CuO3, the evolution of which is reflected by the spectral features of HHs. When the electric-field amplitude exceeds 6 MV/cm, carriers are efficiently generated and each harmonic frequency decreases from odd multiples of the MIR frequency. Dynamical mean-field theory indicates that these redshifts originate from a series of electronic-structure reconstructions in each electric-field cycle during the melting of the Mott-insulator state, which modifies the radiation phase from carrier recombination cycle-by-cycle. This phenomenon is negligible in rigid-band systems. This experimental-theoretical study confirms that HH spectroscopy research can potentially unravel the sub-cycle dynamics of nonequilibrium phase transitions in correlated materials.
title High harmonic generation reflecting the sub-cycle evolution of the Mott transition under a mid-infrared electric field
topic Strongly Correlated Electrons
Optics
url https://arxiv.org/abs/2508.00296