Raman Wavelength Conversion in Ionic Liquids

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Raman Wavelength Conversion in Ionic Liquids

Rotem Kupfer, Furong Wang, James F. Wishart, Marcus Babzien, Mikhail N. Polyanskiy, Igor V. Pogorelsky, Triveni Rao, Luca Cultrera, Navid Vafaei-Najafabadi, and Mark A. Palmer

Phys. Rev. Applied 19, 014052 – Published 19 January 2023

See synopsis: A Salt-Based Laser Color Converter

Abstract

We explore the use of room-temperature ionic liquids (ILs) as Raman wavelength converters. ILs provide an engineerable framework to design suitable liquids for wavelength conversion over a broad spectral range, through careful selection of the molecular structures of the IL anions and cations so that specific characteristics can be obtained, such as a desirable Raman shift, low Brillouin scattering, and good optical transmission in the pump and Stokes wavelengths. Applying such criteria, we demonstrate that 1-ethyl-3-methylimidazolium dicyanamide (EMIM DCA) is an effective medium for conversion of 532-nm pulses from a Q-switched $Nd :$ YAG laser to 603 nm. This corresponds to an approximate 2200 ${cm}^{- 1}$ shift, which can be used to generate mid-infrared radiation through subsequent difference frequency generation for optical pumping of ${CO}_{2}$ lasers. Threefold-higher Raman conversion efficiency is obtained in EMIM DCA compared with water under identical conditions in a proof-of-principle single-pass conversion setup, resulting in an efficient generation of multimillijoule, <6 ns duration, high-quality orange laser pulses in a wavelength region that is difficult to access at high energies. Consequently, we examine ILs representing two other classes of Raman-active functional groups and obtain conversion up to the fifth-order Stokes shift and first anti-Stokes shift. Through the tunable selection of their components and their useful dynamical properties, ILs provide a platform for efficient, simple, and alignment-tolerant high-energy Raman shifting with numerous industrial and technological applications.

Received 16 June 2022
Accepted 8 December 2022

DOI:https://doi.org/10.1103/PhysRevApplied.19.014052

Physics Subject Headings (PhySH)

Chemical Physics & Physical Chemistry Frequency conversion Optical sources & detectors Stimulated Raman scattering

Ionic fluids Molecules Organic compounds

Infrared techniques

Atomic, Molecular & OpticalCondensed Matter, Materials & Applied PhysicsInterdisciplinary Physics

synopsis

A Salt-Based Laser Color Converter

Published 19 January 2023

Artificial salts that are liquid at room temperature can be used to efficiently tune the wavelength of a laser source.

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Authors & Affiliations

Rotem Kupfer ^1,*,§, Furong Wang ^2,†, James F. Wishart ^2,‡, Marcus Babzien¹, Mikhail N. Polyanskiy ¹, Igor V. Pogorelsky¹, Triveni Rao³, Luca Cultrera³, Navid Vafaei-Najafabadi^1,4, and Mark A. Palmer¹

¹Accelerator Test Facility, Brookhaven National Laboratory, Upton, New York 11973 USA
²Chemistry Division, Brookhaven National Laboratory, Upton, New York 11973 USA
³Instrumentation Division, Brookhaven National Laboratory, Upton, New York 11973 USA
⁴Department of Physics and Astronomy, Stony Brook University, Stony Brook, New York 11794, USA

^*kupfer2@llnl.gov
^†fwang1@bnl.gov
^‡wishart@bnl.gov
^§Current address: Lawrence Livermore National Laboratory, Livermore CA 94550, USA

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Vol. 19, Iss. 1 — January 2023

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Figure 1
Spectroscopic measurements of various ionic liquids. (a) Spontaneous Raman spectra of the surveyed ILs. The dominant Raman peak for each liquid is marked with an arrow. (b) Transmission spectra of various ILs showing extended transmission into the infrared compared with water. Note that the spectra are not corrected for Fresnel losses. (The sample of EMIM TCM used contains a colored contaminant that is responsible for the lower transmittance in the UV, but the focus is on the NIR.) (c) Refractive index of EMIM DCA as a function of wavelength at 298 K, (d) refractive index of EMIM DCA at 500 nm as a function of temperature. Abbreviations: (1) Cations: EMIM, 1-ethyl-3-methylimidazolium; P_1,4, 1-butyl-1-methylpyrrolidinium; BzMIM, 1-benzyl-3-methylimidazolium; BzPy, 1-benzylpyridinium; (2) Anions: NTf₂, bis(trifluoromethylsulfonyl)amide; FSA, bis(fluorosulfonyl)amide; DCA, dicyanamide; TCM, tricyanomethanide; TCB, tetracyanoborate; EtOSO₃, ethylsulfate. The ILs reported here are all used as received or synthesized. P_1,4 NTf₂, P_1,4 DCA, BzMIM DCA, EMIM DCA, and EMIM TCM purchased from IoLiTec (Ionic Liquids Technologies GmbH, Heilbronn, Germany). EMIM TCB and P_1,4 TCB purchased from EMD Chemicals. EMIM EtOSO₃ is a commercial sample from Solvent Innovations. EMIM NTf₂ [46], BzPy FSA, BzPy NTf₂ [47], and EMIM FSA [48] prepared in our laboratory.
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Figure 2
Illustration of the experimental setup: The pump source is a frequency doubled $Nd$ :YAG laser at 532 nm. We regulate a p-polarized transmitted pump energy by a λ/2 wave plate (WP) and a thin-film polarizer (TFP) while a reflected s-polarized component is sent to a beam dump (BD). The input pulse shape and energy are monitored with a fast photodiode (PD) and an energy meter (EM). The pump is focused and recollimated using a pair of 50-cm focal length lenses (L1). Back reflection and scattering are monitored using a wedged fused silica window (W) and an energy meter. Within the telescope, the pump passes through a 63-cm-long stainless-steel cell capped with 5-mm-thick sapphire windows and filled with EMIM DCA (IL). At the cell’s output, we observe the profile of the pump or Stokes beam using the reflection from a wedge (W) that is focused to a CCD camera using a 15-cm focal length lens (L2) through a removable notch filter (NF). The pump and Stokes beams are separated by an equilateral prism and sent to two energy meters. The Stokes temporal profile is monitored by a second fast photodiode equipped with a notch filter. The spectrum after the cell is acquired using a fiber-coupled spectrometer (Spec) with the fiber tip pointing to a screen that is inserted into the beam path. Turning mirrors are labeled with M.
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Figure 3
Characterization of high-energy water and EMIM DCA Raman converters. (a) Conversion efficiency to the first Stokes order, defined as the ratio of first Stokes energy over pump energy and adjusted for optical losses in the optics except the liquid itself. EMIM DCA shows lower threshold energy and higher conversion efficiency than water. (b) Backward Brillouin scattering efficiency, defined as the ratio of excess backward signal (on top of reflection from the optics) over pump energy. The Brillouin scattering from EMIM DCA is negligible due to the high viscosity of the IL. (c) Optical spectrum after the converter. Note that the intensity of each peak depends on the orientation of the collection fiber tip and does not represent the actual intensity ratios. (d) Pump and Stokes temporal profiles (averaged over 300 shots) showing temporal shortening of the Stokes pulses. (e),(f) Profiles of the pump and Stokes beams, respectively, at the output of the converter at 25-mJ pump energy. The Stokes profile shows significant effective spatial cleaning of the multimode pump profile. Comparison of (g) fluorescence spectra and (h) UV-vis transmission spectra of a postexperiment EMIM DCA sample with an unused one shows no degradation of the liquid.
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Figure 4
Raman-shifting spectra of (a) P_1,4 NTf₂ and (b) BuPy NTf₂ with the pump wavelength attenuated by a 532-nm notch filter showing anti-Stokes and high-order Stokes conversions. Note that the intensity of each peak depends on the orientation of the collection fiber tip and does not represent the actual intensity ratios.
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