Biexciton in one-dimensional Mott insulators

Abstract: The ultrafast dynamics of correlated electron systems after photoexcitation are now attracting considerable attention. This is based upon recent developments in femtosecond laser technology, which enabled us to detect ultrafast electronic responses to a light pulse in solids [1][2][3][4] . Applications of femtosecond pump-probe spectroscopy to correlated electron systems enable us to observe exotic photoinduced phase transitions 5-18 as represented by a photoinduced Mott-insulator-to-metal transition 6,12,[16]… Show more

“…Continuous structures, such as the DB wires examined in this work, are of particular interest as they have been proposed in prior studies to exhibit more exotic beha-viors through enhanced DB-DB coupling, including spin or ionic ordering [26][27][28][29] similar to that seen in low dimensional Mott insulators. [30][31][32] Experimental exploration of such behaviours has so far been limited to scanning tunneling microscopy (STM) measurements at energies outside the band-gap of the material, where the expected ground state ordering of DB wire structures is convoluted with higher energy features associated with the perturbative nature of a necessary tunneling current. [33][34][35][36][37] In this work, we compliment these former studies with the use of the less perturbative AFM.…”

Ionic charge distributions in silicon atomic surface wires

“…Continuous structures, such as the DB wires examined in this work, are of particular interest as they have been proposed in prior studies to exhibit more exotic beha-viors through enhanced DB-DB coupling, including spin or ionic ordering [26][27][28][29] similar to that seen in low dimensional Mott insulators. [30][31][32] Experimental exploration of such behaviours has so far been limited to scanning tunneling microscopy (STM) measurements at energies outside the band-gap of the material, where the expected ground state ordering of DB wire structures is convoluted with higher energy features associated with the perturbative nature of a necessary tunneling current. [33][34][35][36][37] In this work, we compliment these former studies with the use of the less perturbative AFM.…”

Ionic charge distributions in silicon atomic surface wires

“…H 0 is a conventional Hubbard model with a transfer integral T and on-site Coulomb interaction strength U. According to previous works on ET-F 2 TCNQ [15,43,46], we set U/T = 10. H V describes a long-range Coulomb interaction and V α corresponds to the αth nearest neighbor Coulomb interaction strength.…”

“…Regarding this, the excitonic energy structures of including information of both the odd-and even-parity low-energy one-HD-pair excited states can be estimated by electroreflectance spectroscopy with teraheltz (THz) electric fields. So far, several experiments have reported such excitonic energy structures in Mott insulators deduced from fitting parameters of measured third-order nonlinear susceptibility, χ (3) (−ω; 0, 0, ω) [40][41][42][43].…”

“…As one of such experiments, we choose the recent experiment of ET-F 2 TCNQ at 294 K [43] and reproduce its excitonic energy structure for evaluating the completeness of our evenparity effective model in this paper. In this experiment, χ (3) (−ω; 0, 0, ω) was obtained from a nonlinear polarization P (ω) ∝ χ (3) (−ω; 0, 0, ω)E 2 (ω ∼ 0)E(ω), where E(ω ∼ 0) can be regarded as a static electric field created by a THz pulse and E(ω) is an electric field of optical probe pulse, respectively.…”

“…Using the MBWFs, we also demonstrate the scheme of theoretically calculating σ(ω) with and without a modulated electric field for large system size. All the theoretical spectra and excitonic energy structures compared with corresponding experimental data of ET-F 2 TCNQ at 294 K [43] are shown and discussed in Sect.III. Throughout this paper, we treat absolute zero temperature and set = e = c = a = 1, where a is a lattice constant.…”

Excitonic optical spectra and energy structures in a one-dimensional Mott insulator demonstrated by applying a many-body Wannier functions method to a charge model

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