Terahertz Sum-Frequency Excitation of a Raman-Active Phonon

Maehrlein, Sebastian F.; Paarmann, Alexander; Wolf, Martin; Kampfrath, Tobias

doi:10.1103/physrevlett.119.127402

Cited by 73 publications

(74 citation statements)

References 47 publications

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“…Driving these modes to large amplitudes can enable new insights into their properties. [164] Here, two frequencies of the incident THz pulse induce a force on the lattice oscillating at the sum frequency, rather than the difference frequency that occurs in standard Raman-type excitations. [162,163] Even if the phonon of interest is infrared-inactive yet Ramanactive does THz radiation provide new means of phonon excitation by a Raman-type sum-frequency process.…”

Section: Properties Of Driven Modesmentioning

confidence: 99%

“…For instance, excitation of infrared-optical phonons with intense THz pulses and tracing the anharmonic response [161] allowed one to reconstruct the atomic-scale potential the ions are moving in. [164] This process can also be considered as 2PA by an optical transition between two adjacent vibrational levels. [164] Here, two frequencies of the incident THz pulse induce a force on the lattice oscillating at the sum frequency, rather than the difference frequency that occurs in standard Raman-type excitations.…”

Section: Properties Of Driven Modesmentioning

confidence: 99%

“…[162,163] Even if the phonon of interest is infrared-inactive yet Ramanactive does THz radiation provide new means of phonon excitation by a Raman-type sum-frequency process. [164] Here, two frequencies of the incident THz pulse induce a force on the lattice oscillating at the sum frequency, rather than the difference frequency that occurs in standard Raman-type excitations. By using intense THz pulses centered at 20 THz, Raman-active zone-center optical phonons of diamond at a frequency of 40 THz were successfully excited and phasecoherently controlled.…”

Section: Properties Of Driven Modesmentioning

confidence: 99%

“…By using intense THz pulses centered at 20 THz, Raman-active zone-center optical phonons of diamond at a frequency of 40 THz were successfully excited and phasecoherently controlled. [164] This process can also be considered as 2PA by an optical transition between two adjacent vibrational levels.…”

Section: Properties Of Driven Modesmentioning

confidence: 99%

See 3 more Smart Citations

Laser‐Driven Strong‐Field Terahertz Sources

Fülöp

Tzortzakis

Kampfrath

2019

Advanced Optical Materials

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reason for this interest relies on the fact that THz radiation can couple resonantly to numerous fundamental motions of ions, electrons, and electron spins in all phases of matter. For example, in solids, the THz range overlaps with the frequency of lattice vibrations (phonons), the collision rates of conduction electrons, the binding energy of bound electron-hole pairs (excitons), and the precession frequency of spin waves (magnons). Consequently, THz radiation, both continuous-wave and pulsed, has been used for characterization of and gaining insight into elementary processes in complex materials. The majority of these studies used relatively weak THz fields and, thus, probed the linear response of the material, without inducing notable material modifications.Only recently, however, completely new avenues in THz science were opened up by triggering nonlinear THz responses of materials. [3][4][5][6][7][8][9][10][11][12][13] Instead of using weak fields to primarily observe selected THz modes such as phonons or magnons, strong fields allow one to actively drive them to unprecedentedly large amplitudes, potentially thereby resulting in novel states of matter. [6,8,11] For example, simulations suggest that exciting matter with intense THz transients may lead to massive modifications of electrically [14] or magnetically [15] ordered domains and enable the acceleration of free ions to ≈1 MeV, [16] and postacceleration to 50-100 MeV energies. [17] Remarkable experimental results such as switching of magnetic order, [18,19] parametric amplification of optical phonons, [20] novel insights into spin-lattice coupling, [21,22] and acceleration of free electrons in a THz linear accelerator [23] were achieved only recently. This progress has been made possible by the development of laser-driven table-top THz sources routinely providing pulses with unprecedented energies and peak electric and magnetic field strengths throughout the entire THz spectral range. Different laser-based THz pulse generation techniques can be used to access different parts of the spectral range extending from 0.1 to 10 THz. Some of the recently developed technologies enable the generation of radiation with even larger bandwidth or tuning range up to 100 THz and beyond, which lead to an extension of what is called the THz spectral range. An overview of the approximate spectral coverage and the achieved highest pulse energies and peak electric-field strengths of various laserdriven technologies is given in Figure 1. ScopeIn this work, the basic principles of femtosecond-laser-driven intense pulsed THz sources and their recent development are reviewed. These sources are capable of delivering peak electric field strengths on the MV cm −1 scale. Corresponding typical THz pulse energies are on the µJ-to-mJ level, depending on A review on the recent development of intense laser-driven terahertz (THz) sources is provided here. The technologies discussed include various types of sources based on optical rectification (OR), spintronic emitters, and laserfilame...

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Section: Properties Of Driven Modesmentioning

confidence: 99%

Section: Properties Of Driven Modesmentioning

confidence: 99%

Section: Properties Of Driven Modesmentioning

confidence: 99%

Section: Properties Of Driven Modesmentioning

confidence: 99%

See 2 more Smart Citations

Laser‐Driven Strong‐Field Terahertz Sources

Fülöp

Tzortzakis

Kampfrath

2019

Advanced Optical Materials

Self Cite

253

147

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show abstract

“…The underlying mechanism involves the resonant excitation of large-amplitude infraredactive modes, whose oscillation displaces the crystal along the coordinates of coupled Ramanactive modes. Extending these studies to the insulating parent compounds by employing narrow-band THz fields and sum-frequency ionic Raman scattering [55,56] will realize the mode-selective control of the IMT in the electronic ground state, paving the way to the use of correlated insulators in fast room-temperature devices. Finally, our joint experimentaltheoretical effort points to rational-design strategies for novel quantum materials that exhibit a subtle interplay of electron-electron and electron-phonon interactions.…”

Section: Discussionmentioning

confidence: 99%

Electron–phonon-driven three-dimensional metallicity in an insulating cuprate

Baldini

Sentef

Acharya

et al. 2020

Proc. Natl. Acad. Sci. U.S.A.

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The role of the crystal lattice for the electronic properties of cuprates and other high-temperature superconductors remains controversial despite decades of theoretical and experimental efforts. While the paradigm of strong electronic correlations suggests a purely electronic mechanism behind the insulator-to-metal transition, recently the mutual enhancement of the electron-electron and the electron-phonon interaction and its relevance to the formation of the ordered phases have also been emphasized.Here, we combine polarization-resolved ultrafast optical spectroscopy and state-ofthe-art dynamical mean-field theory to show the importance of the crystal lattice in the breakdown of the correlated insulating state in an archetypal undoped cuprate.We identify signatures of electron-phonon coupling to specific fully-symmetric optical modes during the build-up of a three-dimensional metallic state that follows charge photodoping. Calculations for coherently displaced crystal structures along the relevant phonon coordinates indicate that the insulating state is remarkably unstable toward metallization despite the seemingly large charge-transfer energy scale. This hitherto unobserved insulator-to-metal transition mediated by fully-symmetric lattice modes can find extensive application in a plethora of correlated solids. RESULTS Crystal Structure and Equilibrium Optical PropertiesAs a model material system we study La 2 CuO 4 (LCO), one of the simplest insulating cuprates exhibiting metallicity upon hole doping. In this solid, the two-dimensional network of corner-sharing CuO 4 units is accompanied by two apical O atoms below and above each CuO 4 plaquette. As a result, the main building blocks of LCO are CuO 6 octahedra ( Fig. 1 A) that are elongated along the c-axis due to the Jahn-Teller distortion. The unit cell of LCO is tetragonal above and orthorhombic below 560 K. A simplified scheme of the electronic density of states is shown in Fig. 1 B (left panel). An energy gap (∆ CT ∼2 eV) opens between the filled O-2p band and the unoccupied Cu-3d upper Hubbard band (UHB), thus being of the CT type. In contrast, the occupied Cu-3d lower Hubbard band (LHB) lies at lower energy. First, we present the optical properties of LCO in equilibrium. Figure 1 C shows the absorptive part of the optical conductivity (σ 1 ), measured via ellipsometry. The in-plane response (σ 1a , solid violet curve) is dominated by the optical CT gap at 2.20 eV [17, 18].This transition is a non-local resonant exciton that extends at least over two CuO 4 units.The strong coupling to the lattice degrees of freedom causes its broadened shape [18][19][20]. As such, this optical feature can be modeled as involving the formation of an electron-polaron and a hole-polaron, coupled to each other by a short-range interaction [18,21]. At higher energy (2.50−3.50 eV), the in-plane spectrum results from charge excitations that couple the O-2p states to both the Cu-3d states in the UHB and the La-5d /4f states. In contrast, the out-of-plane optical conductivity (σ ...

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Recent Development of Ultrafast Optical Characterizations for Quantum Materials

2022

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or far-infrared energy region are therefore of particular importance, for the THz frequencies (1 THz≈4.1 meV) are close to the energy scales of a number of important single-particle and collective excitations of quantum material systems, for example, pairing energy gaps of superconductors, lattice vibration modes (phonons), collective spin waves (magnons), Josephson plasmon in high temperature superconductors, and binding energy of bound electron-hole pairs (excitons), [1] and they are linked to a large number of fundamental physical problems currently under intensive investigations in condensed matter physics. The information yielded from equilibrium optical measurements are usually prerequisites for understanding the nonequilibrium optical properties probed by ultrafast time-resolved spectroscopy techniques.In the last three decades, we have witnessed a rapid development in ultrafast laser and nonlinear optical techniques. The intense ultrashort optical pulses at wavelengths spanning the electromagnetic spectrum from terahertz through visible to X-ray have been generated from table-top laser sources and free-electron laser facilities. A variety of time-resolved spectroscopy techniques on the basis of pump-probe scheme have been developed. Depending on the fluence of pump pulses, photoexcitations can induce different effects and phenomena. For sufficiently weak perturbations, the photoexcitation of charge carriers does not change the free-energy landscape and the system relaxes back to the equilibrium state in a short time scale. The relaxation process is determined by the same interactions (e.g for example, electron-electron, electron-phonon) that govern the equilibrium properties. In principle, one can extract the coupling strength of electron to other degrees of freedom from the relaxation dynamics. In addition, the ultrashort laser pulse whose duration is shorter than the periodicity of targeted lattice/spin modes can trigger coherent oscillations at the corresponding frequencies of collective modes, for example, phonon, magnon, etc. with decay times that are related to the dephasing times. This enables one to detect collective-mode excitations that may not be easily accessed to or probed by other techniques.By contrast, with strong pump pulses, the photoexcitation can excite a sufficient number of electrons or drive the motion of collective mode to a large amplitude. The corresponding perturbation to the lattice/spin degrees of freedom can be large enough to modify the free-energy landscape. As a result, The advent of intense ultrashort optical pulses spanning a frequency range from terahertz to the visible has opened a new era in the experimental investigation and manipulation of quantum materials. The generation of strong optical field in an ultrashort time scale enables the steering of quantum materials nonadiabatically, inducing novel phenomenon or creating new phases which may not have an equilibrium counterpart. Ultrafast time-resolved optical techniques have provided rich information and played an im...

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Terahertz Sum-Frequency Excitation of a Raman-Active Phonon

Cited by 73 publications

References 47 publications

Laser‐Driven Strong‐Field Terahertz Sources

Laser‐Driven Strong‐Field Terahertz Sources

Electron–phonon-driven three-dimensional metallicity in an insulating cuprate

Recent Development of Ultrafast Optical Characterizations for Quantum Materials

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