Organic Broadband THz Generators Optimized for Efficient Near‐Infrared Optical Pumping

Organic Broadband THz Generators Optimized for Efficient Near‐Infrared Optical Pumping

Abstract New organic THz generators are designed herein by molecular engineering of the refractive index, phonon mode, and spatial asymmetry. These benzothiazolium crystals simultaneously satisfy the crucial requirements for efficient THz wave generation, including having nonlinear optical chromopho...

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Main Authors: Myeong‐Hoon Shin, Won Tae Kim, Se‐In Kim, Seung‐Jun Kim, In Cheol Yu, Sang‐Wook Kim, Mojca Jazbinsek, Woojin Yoon, Hoseop Yun, Fabian Rotermund, O‐Pil Kwon
Format: Article
Language:English
Published: Wiley 2020-10-01
Series:Advanced Science
Subjects:
nonlinear optics
organic crystals
terahertz waves
Online Access:https://doi.org/10.1002/advs.202001738
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spelling doaj-12bfb4256ff541a282ca2e6207dda95d2020-11-25T03:41:47ZengWileyAdvanced Science2198-38442020-10-01720n/an/a10.1002/advs.202001738Organic Broadband THz Generators Optimized for Efficient Near‐Infrared Optical PumpingMyeong‐Hoon Shin0Won Tae Kim1Se‐In Kim2Seung‐Jun Kim3In Cheol Yu4Sang‐Wook Kim5Mojca Jazbinsek6Woojin Yoon7Hoseop Yun8Fabian Rotermund9O‐Pil Kwon10Department of Molecular Science and Technology Ajou University Suwon 443‐749 KoreaDepartment of Physics Korea Advanced Institute of Science and Technology (KAIST) Daejeon 34141 KoreaDepartment of Molecular Science and Technology Ajou University Suwon 443‐749 KoreaDepartment of Molecular Science and Technology Ajou University Suwon 443‐749 KoreaDepartment of Physics Korea Advanced Institute of Science and Technology (KAIST) Daejeon 34141 KoreaDepartment of Molecular Science and Technology Ajou University Suwon 443‐749 KoreaInstitute of Computational Physics Zurich University of Applied Sciences (ZHAW) Winterthur 8401 SwitzerlandDepartment of Chemistry and Department of Energy Systems Research Ajou University Suwon 443‐749 KoreaDepartment of Chemistry and Department of Energy Systems Research Ajou University Suwon 443‐749 KoreaDepartment of Physics Korea Advanced Institute of Science and Technology (KAIST) Daejeon 34141 KoreaDepartment of Molecular Science and Technology Ajou University Suwon 443‐749 KoreaAbstract New organic THz generators are designed herein by molecular engineering of the refractive index, phonon mode, and spatial asymmetry. These benzothiazolium crystals simultaneously satisfy the crucial requirements for efficient THz wave generation, including having nonlinear optical chromophores with parallel alignment that provide large optical nonlinearity; good phase matching for enhancing the THz generation efficiency in the near‐infrared region; strong intermolecular interactions that provide restraining THz self‐absorption; high solubility that promotes good crystal growth ability; and a plate‐like crystal morphology with excellent optical quality. Consequently, the as‐grown benzothiazolium crystals exhibit excellent characteristics for THz wave generation, particularly at near‐infrared pump wavelengths around 1100 nm, which is very promising given the availability of femtosecond laser sources at this wavelength, where current conventional THz generators deliver relatively low optical‐to‐THz conversion efficiencies. Compared to a 1.0‐mm‐thick ZnTe crystal as an inorganic benchmark, the 0.28‐mm‐thick benzothiazolium crystal yields a 19 times higher peak‐to‐peak THz electric field with a broader spectral bandwidth (>6.5 THz) when pumped at 1140 nm. The present work provides a valuable approach toward realizing organic crystals that can be pumped by near‐infrared sources for efficient THz wave generation.https://doi.org/10.1002/advs.202001738nonlinear opticsorganic crystalsterahertz waves
collection DOAJ
language English
format Article
sources DOAJ
author Myeong‐Hoon Shin
Won Tae Kim
Se‐In Kim
Seung‐Jun Kim
In Cheol Yu
Sang‐Wook Kim
Mojca Jazbinsek
Woojin Yoon
Hoseop Yun
Fabian Rotermund
O‐Pil Kwon
spellingShingle Myeong‐Hoon Shin
Won Tae Kim
Se‐In Kim
Seung‐Jun Kim
In Cheol Yu
Sang‐Wook Kim
Mojca Jazbinsek
Woojin Yoon
Hoseop Yun
Fabian Rotermund
O‐Pil Kwon
Organic Broadband THz Generators Optimized for Efficient Near‐Infrared Optical Pumping
Advanced Science
nonlinear optics
organic crystals
terahertz waves
author_facet Myeong‐Hoon Shin
Won Tae Kim
Se‐In Kim
Seung‐Jun Kim
In Cheol Yu
Sang‐Wook Kim
Mojca Jazbinsek
Woojin Yoon
Hoseop Yun
Fabian Rotermund
O‐Pil Kwon
author_sort Myeong‐Hoon Shin
title Organic Broadband THz Generators Optimized for Efficient Near‐Infrared Optical Pumping
title_short Organic Broadband THz Generators Optimized for Efficient Near‐Infrared Optical Pumping
title_full Organic Broadband THz Generators Optimized for Efficient Near‐Infrared Optical Pumping
title_fullStr Organic Broadband THz Generators Optimized for Efficient Near‐Infrared Optical Pumping
title_full_unstemmed Organic Broadband THz Generators Optimized for Efficient Near‐Infrared Optical Pumping
title_sort organic broadband thz generators optimized for efficient near‐infrared optical pumping
publisher Wiley
series Advanced Science
issn 2198-3844
publishDate 2020-10-01
description Abstract New organic THz generators are designed herein by molecular engineering of the refractive index, phonon mode, and spatial asymmetry. These benzothiazolium crystals simultaneously satisfy the crucial requirements for efficient THz wave generation, including having nonlinear optical chromophores with parallel alignment that provide large optical nonlinearity; good phase matching for enhancing the THz generation efficiency in the near‐infrared region; strong intermolecular interactions that provide restraining THz self‐absorption; high solubility that promotes good crystal growth ability; and a plate‐like crystal morphology with excellent optical quality. Consequently, the as‐grown benzothiazolium crystals exhibit excellent characteristics for THz wave generation, particularly at near‐infrared pump wavelengths around 1100 nm, which is very promising given the availability of femtosecond laser sources at this wavelength, where current conventional THz generators deliver relatively low optical‐to‐THz conversion efficiencies. Compared to a 1.0‐mm‐thick ZnTe crystal as an inorganic benchmark, the 0.28‐mm‐thick benzothiazolium crystal yields a 19 times higher peak‐to‐peak THz electric field with a broader spectral bandwidth (>6.5 THz) when pumped at 1140 nm. The present work provides a valuable approach toward realizing organic crystals that can be pumped by near‐infrared sources for efficient THz wave generation.
topic nonlinear optics
organic crystals
terahertz waves
url https://doi.org/10.1002/advs.202001738
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