Highly Nonlinear Optical Organic Crystals for Efficient Terahertz Wave Generation, Detection, and Applications

Kim, Seung Jun; Kang, Bong Joo; Puc, Uroš; Kim, Dong-Won; Jazbinšek, Mojca; Rotermund, Fabıan; Kwon, O‐Pil

doi:10.1002/adom.202101019

Cited by 82 publications

(110 citation statements)

References 327 publications

(587 reference statements)

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“…From the aforementioned experimental and theoretical results, it is obvious that the diagonal macroscopic optical nonlinearity of OPR crystals is very large and comparable to that of DAST crystals and other various benchmark organic nonlinear optical crystals. [11,34]…”

Section: Opr-ebsmentioning

confidence: 99%

“…When large macroscopic optical nonlinearity is achieved, possessing the shorter absorption wavelength of OPR crystals is very beneficial for achieving different wavelength dependences of both linear and nonlinear optical characteristics, as well as the photochemical stability. [6,34,39,40] For many nonlinear optical applications, it is essential to avoid the absorption at the pump and/or probe wavelengths used, while some may also prefer to match the wavelengths used with the absorption and rely on resonance effects. OPR and DAST crystals are, therefore, expected to exhibit a remarkably different wavelength dependence of their nonlinear optical response.…”

Section: Crystalline Characteristics With Orange Colormentioning

confidence: 99%

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Design Strategy of Highly Efficient Nonlinear Optical Orange‐Colored Crystals with Two Electron‐Withdrawing Groups

Kim

Jazbinšek

et al. 2022

Advanced Photonics Research

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Organic crystals exhibiting second-order optical nonlinearity enable strong interaction of electromagnetic waves and zerofrequency electric fields with matter. These interactions result in changes and modulation of the characteristics of electromagnetic waves such as frequency, phase, time delay, and amplitude. This nonlinear response of organic crystals can be applied for various nonlinear optical and electrooptic applications. [1][2][3][4][5][6][7][8][9][10] In the past few decades, many studies on organic nonlinear optical crystals have been carried out to enhance their macroscopic second-order optical nonlinearity toward improving the nonlinear optical performance. [10,11] However, enhancing the macroscopic optical nonlinearity of organic crystals is highly challenging. In polymeric systems, the required noncentrosymmetric molecular ordering of polar chromophores can be achieved with additional forces (e.g., a poling process using an electric field). [7,12] In the crystalline state, however, such a noncentrosymmetric molecular ordering must be achieved through self-assembly without additional external forces. Consequently, although chromophores themselves may

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Section: Opr-ebsmentioning

confidence: 99%

Section: Crystalline Characteristics With Orange Colormentioning

confidence: 99%

Design Strategy of Highly Efficient Nonlinear Optical Orange‐Colored Crystals with Two Electron‐Withdrawing Groups

Kim

Jazbinšek

et al. 2022

Advanced Photonics Research

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“…For instance, in organic π ‐conjugated materials, the so‐called molecular phonons play an important role for their functional properties, such as the charge mobility, [ 11–13 ] emission characteristics, [ 14,15 ] as well as the absorption and refractive index characteristics at far‐infrared and THz frequencies. [ 16–27 ]…”

Section: Introductionmentioning

confidence: 99%

“…Such hydrogen bonds present main interionic interactions in several promising recently developed organic salt crystals for THz wave generation. [ 16,17 ] Note that in many organic THz generators, aromatic (i.e., phenolic) and aliphatic OH groups are incorporated. In this work, we introduce two phenolic OH groups for the design of new organic THz device materials.…”

Section: Introductionmentioning

confidence: 99%

Phonon‐Suppressing Intermolecular Adhesives: Catechol‐Based Broadband Organic THz Generators

et al. 2022

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Solid-state molecular phonons play a crucial role in the performance of diverse photonic and optoelectronic devices. In this work, new organic terahertz (THz) generators based on a catechol group that acts as a phonon suppressing intermolecular adhesive are developed. The catechol group is widely used in mussel-inspired mechanical adhesive chemistry. Newly designed organic electro-optic crystals consist of catechol-based nonlinear optical 4-(3,4-dihydroxystyryl)-1-methylpyridinium (DHP) cations and 4-(trifluoromethyl)benzenesulfonate anions (TFS), which both have multiple interionic interaction capability. Interestingly, compared to benchmark organic crystals for THz generators, DHP-TFS crystals concomitantly achieve top level values of the lowest void volume and the highest crystal density, resulting in an exceptionally small amplitude of solid-state molecular phonons. Simultaneously achieving small molecular phonon amplitude, large optical nonlinearity and good phase matching at infrared optical pump wavelengths, DHP-TFS crystals are capable of generating broadband THz waves of up to 16 THz with high optical-to-THz conversion efficiency; one order of magnitude higher than commercial inorganic THz generators.

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“…Coherent optical control of quantum many-body systems has also been recognized as an intriguing problem in modern condensed matter physics, since such a system exhibits a wide variety of phases and thereby provides a rich playground for the control of physical properties. Recent developments in photoinduced phase transitions [25][26][27][28] and Floquet engineering [29][30][31][32][33] have attracted growing interest in studying the ultrafast and nonthermal control of quantum materials, owing to the rapid development of light sources [34][35][36][37] and of timeresolved measurement techniques [25,29,[38][39][40][41][42][43][44][45][46][47][48][49]. However, the coherent control of condensed matter systems still faces challenges, since quantum coherence is quickly destroyed by interactions with environmental degrees of freedom.…”

Section: Introductionmentioning

confidence: 99%

Energy-band echoes: Time-reversed light emission from optically driven quasiparticle wavepackets

Imai¹,

Ono²,

Ishihara³

2022

Preprint

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The at-will control of quantum states is a primary goal of quantum science and technology. The celebrated Hahn echo exemplifies such quantum-state control based on a time-reversal process in a few-level system. Here, we propose a different echo phenomenon associated with the energy-band structure in quantum many-body systems. We show that the dynamics of quasiparticle wavepackets can be reversed by a driving electric-field pulse, yielding echoes with the time-reversed waveform of the optical excitation pulse when the quasiparticles recombine. The present echoes are observed not only in band insulators but also in correlated insulators, including a Mott insulator and a spontaneously-broken-symmetry charge-ordered insulator, in one-and higherdimensional systems, irrespective of the integrability of the models. Analytical expressions reveal the conditions under which the echoes appear, and they also indicate that the frequency of the echo pulses reflects the dispersion relation for quasiparticles such as electron-hole pairs, doublon-holon pairs, and kink-antikink pairs. These findings provide a framework for all-optical momentum-resolved spectroscopy of the quasiparticles in quantum many-body systems.

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Highly Nonlinear Optical Organic Crystals for Efficient Terahertz Wave Generation, Detection, and Applications

Cited by 82 publications

References 327 publications

Design Strategy of Highly Efficient Nonlinear Optical Orange‐Colored Crystals with Two Electron‐Withdrawing Groups

Design Strategy of Highly Efficient Nonlinear Optical Orange‐Colored Crystals with Two Electron‐Withdrawing Groups

Phonon‐Suppressing Intermolecular Adhesives: Catechol‐Based Broadband Organic THz Generators

Energy-band echoes: Time-reversed light emission from optically driven quasiparticle wavepackets

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