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Journal articles on the topic 'IR-UV Double Resonance Spectroscopy'

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Published: 10 December 2022
Last updated: 28 January 2023

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1

Callahan, Michael P., Bridgit Crews, Ali Abo-Riziq, Louis Grace, Mattanjah S. de Vries, Zsolt Gengeliczki, Tiffani M. Holmes, and Glake A. Hill. "IR-UV double resonance spectroscopy of xanthine." Physical Chemistry Chemical Physics 9, no. 32 (2007): 4587. http://dx.doi.org/10.1039/b705042a.

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2

Crews, Bridgit, Ali Abo-Riziq, Louis Grace, Michael Callahan, Martin Kabeláč, Pavel Hobza, and Mattanjah S. de Vries. "IR-UV double resonance spectroscopy of guanine–H2O clusters." Physical Chemistry Chemical Physics 7, no. 16 (2005): 3015. http://dx.doi.org/10.1039/b506107e.

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3

Plützer, Chr, E. Nir, M. S. de Vries, and K. Kleinermanns. "IR–UV double-resonance spectroscopy of the nucleobase adenine." Physical Chemistry Chemical Physics 3, no. 24 (December 5, 2001): 5466–69. http://dx.doi.org/10.1039/b107997b.

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4

Inokuchi, Yoshiya, Yusuke Kobayashi, Takafumi Ito, and Takayuki Ebata. "Conformation ofl-Tyrosine Studied by Fluorescence-Detected UV−UV and IR−UV Double-Resonance Spectroscopy." Journal of Physical Chemistry A 111, no. 17 (May 2007): 3209–15. http://dx.doi.org/10.1021/jp070163a.

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5

Bouchet, Aude, Johanna Klyne, Shun-ichi Ishiuchi, Otto Dopfer, Masaaki Fujii, and Anne Zehnacker. "Stereochemistry-dependent structure of hydrogen-bonded protonated dimers: the case of 1-amino-2-indanol." Physical Chemistry Chemical Physics 20, no. 18 (2018): 12430–43. http://dx.doi.org/10.1039/c8cp00787j.

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Stereochemistry effects on the structure of molecular aggregates are studied in the prototypical 1-amino-2-indanol. Conformer-selective IR-UV double resonance spectroscopy reveals how stereochemistry shapes its dimers.
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6

Abo-Riziq, Ali G., Bridgit Crews, John E. Bushnell, Michael P. Callahan, and Mattanjah S. De Vries *. "Conformational analysis of cyclo(Phe-Ser) by UV–UV and IR–UV double resonance spectroscopy andab initiocalculations." Molecular Physics 103, no. 11-12 (June 10, 2005): 1491–95. http://dx.doi.org/10.1080/00268970500095923.

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7

Chadwick, B. L., A. P. Milce, and B. J. Orr. "Fluorescence-detected infrared– and Raman–ultraviolet double resonance in acetylene gas: studies of spectroscopy and rotational energy transfer." Canadian Journal of Physics 72, no. 11-12 (November 1, 1994): 939–53. http://dx.doi.org/10.1139/p94-124.

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Fluorescence-detected Raman–ultraviolet and infrared–ultraviolet double resonance (DR) spectroscopy enables state-selective studies of rotational and vibrational energy transfer in gas-phase acetylene (C2H2) and its deuterated isotopomers (C2HD, C2D2). The Raman–UV DR approach entails pulsed coherent Raman excitation in the ν2 rovibrational band of C2H2(g), followed by fluorescence-detected rovibronic probing of the resulting rovibrational population distributions. Corresponding IR–UV DR experiments employ a line-tunable, pulsed CO2 laser to excite rovibrational transitions in the 2ν4 band of C2HD(g) and in the (ν4 + ν5) band of C2D2(g), with similar fluorescence-detected rovibronic probing. These time-resolved DR spectroscopic techniques provide rotationally specific information on collision-induced molecular energy transfer in acetylene. This paper extends previous Raman–UV DR spectroscopic studies of C2H2 and presents fresh IR–UV DR spectra of gas-phase C2HD and C2D2, including evidence of a novel two-step excitation sequence in which a single CO2-laser pulse promotes C2D2 by successive transitions in the (ν4 + v5) and (2ν4 + 2ν5−ν4−v5) absorption bands. Kinetic measurements and mechanistic observations are also reported for collision-induced rotational energy transfer in acetylene gas, complementing other investigations of rotationally resolved vibrational energy transfer.
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8

Mahé, Jérôme, Sander Jaeqx, Anouk M. Rijs, and Marie-Pierre Gaigeot. "Can far-IR action spectroscopy combined with BOMD simulations be conformation selective?" Physical Chemistry Chemical Physics 17, no. 39 (2015): 25905–14. http://dx.doi.org/10.1039/c5cp01518a.

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The combination of conformation selective far-IR/UV double resonance spectroscopy with Born–Oppenheimer molecular dynamics (BOMD) simulations is presented here for the structural characterization of the Ac-Phe-Pro-NH2 peptide in the far-infrared spectral domain, i.e. for radiation below 800 cm−1.
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9

Asami, Hiroya, Shu-hei Urashima, and Hiroyuki Saigusa. "Structural identification of uric acid and its monohydrates by IR-UV double resonance spectroscopy." Physical Chemistry Chemical Physics 13, no. 45 (2011): 20476. http://dx.doi.org/10.1039/c1cp22540e.

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10

Lettenberger, M., F. Emmerling, N. H. Gottfried, and A. Laubereau. "Orientational motion of anthracene in liquid solution studied by IR/UV double-resonance spectroscopy." Chemical Physics Letters 240, no. 4 (June 1995): 324–29. http://dx.doi.org/10.1016/0009-2614(95)00528-c.

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11

Abo-Riziq, Ali G., John E. Bushnell, Bridgit Crews, Michael P. Callahan, Louis Grace, and Mattanjah S. De Vries. "Discrimination between diastereoisomeric dipeptides by IR-UV double resonance spectroscopy and ab initio calculations." International Journal of Quantum Chemistry 105, no. 4 (2005): 437–45. http://dx.doi.org/10.1002/qua.20719.

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12

Fujii, Masaaki, Shigeki Tanabe, Yasuo Okuzawa, and Mitsuo Ito. "IR-UV Double Resonance Spectrum of Acetylene Below and Above the Predissociation Threshold." Laser Chemistry 14, no. 1-3 (January 1, 1994): 161–82. http://dx.doi.org/10.1155/1994/76165.

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The Ã1Au ← X˜1∑g+ electronic transition of the vibrationally excited acetylene molecule was studied by IR–UV double resonance spectroscopy in gas and in a supersonic jet. The C–H antisymmetric stretching vibration νCHant in the à state was clearly observed when the molecule was excited to the νCHsym + νCHant combination vibration in the X˜ state by the IR laser. When the νCHant fundamental vibration was excited, the C–H in-plane cis-bending vibration νcis(in) in the à state was observed strongly, while νCHant almost disappeared. The difference was interpreted in terms of Fermi resonance of the νCHant fundamental vibration in X˜. The predissociation threshold was newly determined to be 46,439˼46,673 cm-1 (133.11 ± 0.33 kcal/mol). In the region above the predissociation threshold, strong vibrational mixing was found. The higher members of the progression of the trans-bending vibration starting from νCHant were assigned. It was suggested that the nonradiative relaxation accelerated in the region above 51,744 cm-1.
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13

Bhattacherjee, Aditi, and Sanjay Wategaonkar. "Conformational preferences of monohydrated clusters of imidazole derivatives revisited." Physical Chemistry Chemical Physics 17, no. 31 (2015): 20080–92. http://dx.doi.org/10.1039/c5cp02422f.

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IR-UV double resonance spectroscopy was used to identify the conformers of monohydrated benzimidazole andN-methylbenzimidazole in a supersonic jet. A new OH–N bound conformer relevant to histidine containing proteins was discovered. The long standing differences in the literature about the relative energies and abundance of the monohydrated imidazole derivatives have also been resolved.
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14

Asami, Hiroya, Shu-hei Urashima, and Hiroyuki Saigusa. "Hydration structures of 2′-deoxyguanosine studied by IR-UV double resonance spectroscopy: comparison with guanosine." Physical Chemistry Chemical Physics 11, no. 44 (2009): 10466. http://dx.doi.org/10.1039/b912684h.

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15

Fehrensen, Benjamin, Michael Hippler, and Martin Quack. "Isotopomer-selective overtone spectroscopy by ionization detected IR+UV double resonance of jet-cooled aniline." Chemical Physics Letters 298, no. 4-6 (December 1998): 320–28. http://dx.doi.org/10.1016/s0009-2614(98)01216-0.

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16

Palmer, Phillip M., Yu Chen, and Michael R. Topp. "Simple water clusters of Coumarins 151 and 152A studied by IR–UV double resonance spectroscopy." Chemical Physics Letters 318, no. 4-5 (February 2000): 440–47. http://dx.doi.org/10.1016/s0009-2614(00)00036-1.

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17

Walther, Th, H. Bitto, T. K. Minton, and J. Robert Huber. "UV-IR double-resonance spectroscopy of jet-cooled propynal detected by the fluorescence dip method." Chemical Physics Letters 231, no. 1 (December 1994): 64–69. http://dx.doi.org/10.1016/0009-2614(94)01224-5.

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18

Douberly, Gary E., Jeremy M. Merritt, and Roger E. Miller. "IR–IR double resonance spectroscopy in helium nanodroplets: Photo-induced isomerization." Phys. Chem. Chem. Phys. 7, no. 3 (2005): 463–68. http://dx.doi.org/10.1039/b417553k.

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19

Bykov, Sergei, Igor Lednev, Anatoli Ianoul, Aleksandr Mikhonin, Calum Munro, and Sanford A. Asher. "Steady-State and Transient Ultraviolet Resonance Raman Spectrometer for the 193–270 nm Spectral Region." Applied Spectroscopy 59, no. 12 (December 2005): 1541–52. http://dx.doi.org/10.1366/000370205775142511.

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We describe a state-of-the-art tunable ultraviolet (UV) Raman spectrometer for the 193–270 nm spectral region. This instrument allows for steady-state and transient UV Raman measurements. We utilize a 5 kHz Ti-sapphire continuously tunable laser (∼20 ns pulse width) between 193 nm and 240 nm for steady-state measurements. For transient Raman measurements we utilize one Coherent Infinity YAG laser to generate nanosecond infrared (IR) pump laser pulses to generate a temperature jump (T-jump) and a second Coherent Infinity YAG laser that is frequency tripled and Raman shifted into the deep UV (204 nm) for transient UV Raman excitation. Numerous other UV excitation frequencies can be utilized for selective excitation of chromophoric groups for transient Raman measurements. We constructed a subtractive dispersion double monochromator to minimize stray light. We utilize a new charge-coupled device (CCD) camera that responds efficiently to UV light, as opposed to the previous CCD and photodiode detectors, which required intensifiers for detecting UV light. For the T-jump measurements we use a second camera to simultaneously acquire the Raman spectra of the water stretching bands (2500–4000 cm−1) whose band-shape and frequency report the sample temperature.
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20

Nir, Eyal, Christoph Janzen, Petra Imhof, Karl Kleinermanns, and Mattanjah S. de Vries. "Pairing of the nucleobase guanine studied by IR–UV double-resonance spectroscopy and ab initio calculations." Physical Chemistry Chemical Physics 4, no. 5 (January 29, 2002): 740–50. http://dx.doi.org/10.1039/b110360c.

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21

Plützer, Chr, I. Hünig, and K. Kleinermanns. "Pairing of the nucleobase adenine studied by IR-UV double-resonance spectroscopy and ab initio calculations." Physical Chemistry Chemical Physics 5, no. 6 (February 3, 2003): 1158–63. http://dx.doi.org/10.1039/b212338j.

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22

Nagornova, Natalia S., Thomas R. Rizzo, and Oleg V. Boyarkin. "Exploring the Mechanism of IR-UV Double-Resonance for Quantitative Spectroscopy of Protonated Polypeptides and Proteins." Angewandte Chemie International Edition 52, no. 23 (April 25, 2013): 6002–5. http://dx.doi.org/10.1002/anie.201301656.

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23

Nagornova, Natalia S., Thomas R. Rizzo, and Oleg V. Boyarkin. "Exploring the Mechanism of IR-UV Double-Resonance for Quantitative Spectroscopy of Protonated Polypeptides and Proteins." Angewandte Chemie 125, no. 23 (April 25, 2013): 6118–21. http://dx.doi.org/10.1002/ange.201301656.

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24

Bahnmaier, Albert H., Reiner Schmid, Bing Zhang, and Harold Jones. "Highly Sensitive Infrared Spectroscopy: IR-REMPI Double Resonance Experiments." Berichte der Bunsengesellschaft für physikalische Chemie 96, no. 9 (September 1992): 1305–8. http://dx.doi.org/10.1002/bbpc.19920960947.

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25

Blodgett, Karl N., Joshua L. Fischer, Timothy S. Zwier, and Edwin L. Sibert. "The missing NH stretch fundamental in S1 methyl anthranilate: IR-UV double resonance experiments and local mode theory." Physical Chemistry Chemical Physics 22, no. 25 (2020): 14077–87. http://dx.doi.org/10.1039/d0cp01916j.

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26

Kim, Minho, Sang-Su Kim, Hyuk Kang, and Young Dong Park. "REMPI and IR-UV double resonance spectroscopy of 3-aminophenol·(NH3)1 cluster in the gas phase." Journal of Molecular Spectroscopy 263, no. 1 (September 2010): 51–55. http://dx.doi.org/10.1016/j.jms.2010.06.011.

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27

Ishikawa, Haruki, Chioko Nagao, and Naohiko Mikami. "Observation of the νCHExcited Vibrational Levels in theÃ1A″State of HCP by IR–UV Double Resonance Spectroscopy." Journal of Molecular Spectroscopy 194, no. 1 (March 1999): 52–60. http://dx.doi.org/10.1006/jmsp.1998.7757.

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28

Wen, B., Y. Kim, H. Meyer, J. Kłos, and M. H. Alexander. "IR-REMPI Double Resonance Spectroscopy: The Near-IR Spectrum of NO−Ar Revisited†." Journal of Physical Chemistry A 112, no. 39 (October 2, 2008): 9483–93. http://dx.doi.org/10.1021/jp802765z.

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29

Mizoguchi, Miwako, Nami Yamakita, Soji Tsuchiya, Atsushi Iwasaki, Kennosuke Hoshina, and Kaoru Yamanouchi. "IR−UV Double Resonance Spectroscopy of Acetylene in the Ã1Aunν3‘+ν4‘ andnν3‘+ν6‘ (n= 2, 3)UngeradeVibrational States†." Journal of Physical Chemistry A 104, no. 45 (November 2000): 10212–19. http://dx.doi.org/10.1021/jp001215y.

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30

Tanabe, Shigeki, Takayuki Ebata, Masaaki Fujii, and Naohiko Mikami. "OH stretching vibrations of phenol—(H2O)n (n=1–3) complexes observed by IR-UV double-resonance spectroscopy." Chemical Physics Letters 215, no. 4 (December 1993): 347–52. http://dx.doi.org/10.1016/0009-2614(93)85726-5.

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31

Urashima, Shu-hei, Mitsuhiko Miyazaki, Masaaki Fujii, and Hiroyuki Saigusa. "IR–UV Double Resonance Spectroscopy as Implemented by Polarized Laser Schemes: Probing Orientations of Vibrational Transition Dipole Moments." Chemistry Letters 42, no. 9 (September 5, 2013): 1070–72. http://dx.doi.org/10.1246/cl.130425.

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32

Okuzawa, Yasuo, Masaaki Fujii, and Mitsuo Ito. "Direct observation of second excited 1,3 (n,π*) states of pyrazine by UV—IR double resonance dip spectroscopy." Chemical Physics Letters 171, no. 4 (August 1990): 341–46. http://dx.doi.org/10.1016/0009-2614(90)85374-l.

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33

Fricke, Holger, Andreas Funk, Thomas Schrader, and Markus Gerhards. "Investigation of Secondary Structure Elements by IR/UV Double Resonance Spectroscopy: Analysis of an Isolated β-Sheet Model System." Journal of the American Chemical Society 130, no. 14 (April 2008): 4692–98. http://dx.doi.org/10.1021/ja076031c.

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34

Payne, Mark A., Angela P. Milce, Michael J. Frost, and Brian J. Orr. "Rovibrational Energy Transfer in the 4νCHManifold of Acetylene, Viewed by IR−UV Double Resonance Spectroscopy. 5. Detailed Kinetic Model†." Journal of Physical Chemistry A 111, no. 49 (December 2007): 12839–53. http://dx.doi.org/10.1021/jp0767617.

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35

Kim, Y., J. Fleniken, and H. Meyer. "The NO(X2Π)–Ne complex. I. IR-REMPI double resonance spectroscopy." Journal of Chemical Physics 114, no. 13 (April 2001): 5577–87. http://dx.doi.org/10.1063/1.1349085.

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36

Mizugai, Yoshihiro, Jody J. Klaassen, Christine Roche, and Jeffrey I. Steinfeld. "Overtone Spectra of CHD3 with an FT-IR Spectrometer Aided by Infrared Double Resonance." Applied Spectroscopy 47, no. 12 (December 1993): 2058–60. http://dx.doi.org/10.1366/0003702934066370.

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We have used a time-resolved double-resonance (pump-probe) method to assign the CHD3 spectra taken by an FT-IR spectrometer at high resolution. The spectra of 2ν3, ν3 + ν6, and 2ν6 around 2000 cm−1 were investigated. Collisional processes in the molecule were investigated by the time evolution of the signal and double-resonance spectra.
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37

Carr, J. K., A. V. Zabuga, S. Roy, T. R. Rizzo, and J. L. Skinner. "Assessment of amide I spectroscopic maps for a gas-phase peptide using IR-UV double-resonance spectroscopy and density functional theory calculations." Journal of Chemical Physics 140, no. 22 (June 14, 2014): 224111. http://dx.doi.org/10.1063/1.4882059.

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38

Kolenbrander, Kirk D., Clifford E. Dykstra, and James M. Lisy. "Torsional vibrational modes of (HF)3: IR–IR double resonance spectroscopy and electrical interaction theory." Journal of Chemical Physics 88, no. 10 (May 15, 1988): 5995–6012. http://dx.doi.org/10.1063/1.454492.

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39

Singh, Prashant Chandra, and G. Naresh Patwari. "IR−UV Double Resonance Spectroscopic Investigation of Phenylacetylene−Alcohol Complexes. Alkyl Group Induced Hydrogen Bond Switching." Journal of Physical Chemistry A 112, no. 23 (June 2008): 5121–25. http://dx.doi.org/10.1021/jp800968g.

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40

Payne, Mark A., Angela P. Milce, Michael J. Frost, and Brian J. Orr. "Rovibrational Energy Transfer in the 4νCHManifold of Acetylene, Viewed by IR−UV Double Resonance Spectroscopy. 1. Foundation Studies at LowJ†." Journal of Physical Chemistry A 107, no. 49 (December 2003): 10759–70. http://dx.doi.org/10.1021/jp035224t.

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41

Matsumoto, Y., T. Ebata, and N. Mikami. "Structures and vibrations of 2-naphthol–(NH3) (n=1–3) hydrogen-bonded clusters investigated by IR–UV double-resonance spectroscopy." Journal of Molecular Structure 552, no. 1-3 (September 2000): 257–71. http://dx.doi.org/10.1016/s0022-2860(00)00490-7.

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42

Matsumoto, Yoshiteru, Takayuki Ebata, and Naohiko Mikami. "OH stretching vibrations and hydrogen-bonded structures of 7-hydroxyquinoline-(H2O)1–3 investigated by IR–UV double-resonance spectroscopy." Chemical Physics Letters 338, no. 1 (April 2001): 52–60. http://dx.doi.org/10.1016/s0009-2614(01)00226-3.

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43

Guchhait, Nikhil. "Benzyl alcohol-ammonia (1:1) cluster structure investigated by combined IR-UV double resonance spectroscopy in jet andab initio calculation." Journal of Chemical Sciences 113, no. 3 (June 2001): 235–44. http://dx.doi.org/10.1007/bf02704073.

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44

Gerhards, M., and C. Unterberg. "IR double-resonance spectroscopy applied to the 4-aminophenol(H2O)1 cluster." Applied Physics A Materials Science & Processing 72, no. 3 (March 2001): 273–79. http://dx.doi.org/10.1007/s003390100765.

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45

Stiefvater, Otto L. "High-Resolution Vibrational Spectra of Furazan." Zeitschrift für Naturforschung A 46, no. 10 (October 1, 1991): 841–50. http://dx.doi.org/10.1515/zna-1991-1002.

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AbstractThe study by Fourier transform (FT) infrared (IR) spectroscopy of the fundamental vibrational bands v12 and v5 of furazan yields the origins of these bands with a statistical uncertainty of 10-6 cm-1, which leads to an estimated absolute uncertainty of 10-4 cm-1. The values are v°12 = 952.6123 cm -1 and v°5 = 1.005.3536 cm -1. They confirm the values previously deduced from laser/microwave double resonance (LMDR) experiments. Previous results for the molecular constants of the vibrational ground state and of the two vibrationally excited states, as obtained by double resonance modulation (DRM) microwave spectroscopy alone, are confirmed and refined. Advantages brought about through the combination of the DRM microwave and the FT-IR technique are outlined.
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46

Matsuda, Yoshiyuki, Takayuki Ebata, and Naohiko Mikami. "IR−UV Double-Resonance Spectroscopic Study of 2-Hydroxypyridine and Its Hydrogen-Bonded Clusters in Supersonic Jets." Journal of Physical Chemistry A 105, no. 14 (April 2001): 3475–80. http://dx.doi.org/10.1021/jp003272x.

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47

Payne, Mark A., Angela P. Milce, Michael J. Frost, and Brian J. Orr. "Rovibrational Energy Transfer in the 4νCHManifold of Acetylene, Viewed by IR-UV Double Resonance Spectroscopy. 3. State-to-StateJ-Resolved Kinetics." Zeitschrift für Physikalische Chemie 219, no. 5-2005 (May 2005): 601–33. http://dx.doi.org/10.1524/zpch.219.5.601.64327.

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48

Carter, Robert T., Th Walther, H. Bitto, and J. Robert Huber. "Nuclear quadrupole quantum beat spectroscopy in the electronic ground state of a polyatomic molecule by an IR-UV double resonance method." Chemical Physics Letters 240, no. 1-3 (June 1995): 79–83. http://dx.doi.org/10.1016/0009-2614(95)00474-i.

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49

Nagornova, Natalia S., Thomas R. Rizzo, and Oleg V. Boyarkin. "Titelbild: Exploring the Mechanism of IR-UV Double-Resonance for Quantitative Spectroscopy of Protonated Polypeptides and Proteins (Angew. Chem. 23/2013)." Angewandte Chemie 125, no. 23 (May 9, 2013): 6001. http://dx.doi.org/10.1002/ange.201303560.

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50

Wako, Hiromichi, Shun-ichi Ishiuchi, Daichi Kato, Géraldine Féraud, Claude Dedonder-Lardeux, Christophe Jouvet, and Masaaki Fujii. "A conformational study of protonated noradrenaline by UV–UV and IR dip double resonance laser spectroscopy combined with an electrospray and a cold ion trap method." Physical Chemistry Chemical Physics 19, no. 17 (2017): 10777–85. http://dx.doi.org/10.1039/c6cp08426e.

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