Preparation and Spectral Characterization of Novel Species in Matrices

Lee, Yuan‐Pern

doi:10.1002/jccs.200500091

Cited by 12 publications

References 63 publications

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Matrix Isolation Spectroscopy in Atmospheric Chemistry – Structure and Reactions of Atmospherically Important Species

Karir

Viswanathan

2020

Encyclopedia of Analytical Chemistry

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Atmospheric chemistry has today grown from being a curiosity‐driven science to one that is necessity driven. A plethora of experimental and computational tools are used today to study the chemistry of our atmosphere, in an effort to preserving its health. In this article, we review the use of matrix isolation spectroscopy in the study of atmospheric processes. Most of the chemical reactions in the atmosphere are driven by light and hence photochemical studies of species present in the atmosphere are of great interest. Furthermore, atmospheric chemistry is also dominated by photochemically induced free radical chemistry, and hence techniques to study these reactive species must be resorted to. Matrix isolation spectroscopy is ideally suited for photochemical studies and for the study of reactive short‐lived species and has, therefore, been extensively used. In this article, we particularly discuss the chemistry and the role played by species such as OH ⋅ radicals, NO 3 radicals, and O 3 together with a variety of reactive species involving Br, F, and S. The use and chemistry of alternatives for chlorofluorocarbon s ( CFC s) are also discussed. As a result of the various studies, it has now become possible to understand the role of various species in the atmosphere and therefore to evolve administrative regulations that seek to preserve the health of the atmosphere.

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Matrix Isolation Spectroscopy in Atmospheric Chemistry – Structure and Reactions of Atmospherically Important Species

Karir

Viswanathan

2020

Encyclopedia of Analytical Chemistry

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Advances in Use of p‐H₂ as a Novel Host for Matrix IR Spectroscopy

Bahou¹,

Huang²,

Huang³

et al. 2010

J Chinese Chemical Soc

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A review of recent advances in IR spectroscopy using p-H 2 as a matrix host in our laboratory is presented. The softness of this novel p-H 2 matrix host not only makes high-resolution spectroscopy feasible but also provides new applications. Molecular motion, such as the rotation of C 2 H 4 , internal rotation (torsion) of CH 3 OH, and rotation of CH 3 F about a single axis are characterized in this p-H 2 matrix. In contrast, no evidence for rotation of CH 3 I and CH 3 was found. The diminution of the cage effect leads to the possibility of production of free radicals via either photolysis in situ or bimolecular reactions of molecules with atoms that are produced in situ from their molecular precursors. Taking advantage of these unique features, we identified the IR spectrum of CH 3 produced from photolysis of CH 3 I and CH 3 S produced from photolysis of CH 3 SCH 3 and CH 3 SSCH 3 . The reaction of Cl with CS 2 in solid p-H 2 yields ClSCS instead of ClCS 2 . The reaction of Cl with HCOOH in solid p-H 2 yields only a complex, Cl×HCOOH, not HCl and HOCO. The presence of o-H 2 in trace proportions turned out to be an important factor in the interpretation of IR spectra of species embedded in solid p-H 2 . Experimental techniques to minimize the amount of o-H 2 and to characterize its relative concentration with spectra of H 2 O×o-H 2 are discussed.

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Transient Infrared Absorption Spectra of Reaction Intermediates Detected with a Step‐scan Fourier‐transform Infrared Spectrometer

Huang

Chen

Hsu

et al. 2013

J Chinese Chemical Soc

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Our group has utilized a step-scan FTIR spectrometer operating in the absorption mode to characterize transient species in chemical reactions upon photo-irradiation of gaseous mixtures in a multipass White cell. The operational temporal resolution is typically 1-10 ms with spectral resolution 0.1-4 cm -1 , depending on conditions. The acquisition of both ac-and dc-coupled signals enables an extraction of minute changes in the large background signal to attain a typical detectable absorbance variation greater than 11 0 -4 . By consideration of reaction mechanisms and comparison of vibrational wavenumbers, IR intensities, and rotational contours predicted with theoretical calculations, we have assigned IR absorption bands of many important atmospheric free radicals and unstable species including their conformers, such as ClCO, ClSO, ClCS, ClCOOH, CH 3 SO 2 , CH 3 SOO, CH 3 OSO, CH 3 SO, CH 3 OO, CH 3 C(O)OO, CH 2 OO C 6 H 5 CO, C 6 H 5 SO 2 , and C 6 H 5 C(O)OO. The advantages and limitations of this technique to perform spectral and kinetic investigations of transient species in chemical reactions are discussed. (2010-). His main research interests focus on the spectroscopy, kinetics, and ion pumps of the photosynthetic proteins, using various time-resolved approaches including step-scan FTIR, nanosecond-resolved transient absorption, and electrochemical methods. Chiao Tung University. The main research topics pursued concern spectroscopy, kinetics and dynamics of free radicals or unstable species, using diverse methods including step-scan time-resolved FTIR (emission or absorption), matrix isolation using p-H 2 , cavity ringdown, IR-VUV photoionization, and ultrafast lasers. He has identified more than 70 new free radicals, most of which are important in atmospheric, combustion, or planetary chemistry. He has received numerous honors, and was elected asThe step-scan measurements are performed under the master mode of the spectrometer (Thermo Nicolet, NEXUS 870), in which the timing trigger is initiated by the spectrometer. Figure 3 CHEMICAL SOCIETY Fig. 5. Schematic of the White cell. The first and second IR beam paths and the first and second UV photolysis beam paths of the multiply reflected light are shown. Circular dots indicate images of the IR beam at each reflection.

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Preparation and Spectral Characterization of Novel Species in Matrices

Cited by 12 publications

References 63 publications

Matrix Isolation Spectroscopy in Atmospheric Chemistry – Structure and Reactions of Atmospherically Important Species

Matrix Isolation Spectroscopy in Atmospheric Chemistry – Structure and Reactions of Atmospherically Important Species

Advances in Use of p‐H₂ as a Novel Host for Matrix IR Spectroscopy

Transient Infrared Absorption Spectra of Reaction Intermediates Detected with a Step‐scan Fourier‐transform Infrared Spectrometer

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Preparation and Spectral Characterization of Novel Species in Matrices

Cited by 12 publications

References 63 publications

Matrix Isolation Spectroscopy in Atmospheric Chemistry – Structure and Reactions of Atmospherically Important Species

Matrix Isolation Spectroscopy in Atmospheric Chemistry – Structure and Reactions of Atmospherically Important Species

Advances in Use of p‐H2 as a Novel Host for Matrix IR Spectroscopy

Transient Infrared Absorption Spectra of Reaction Intermediates Detected with a Step‐scan Fourier‐transform Infrared Spectrometer

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Advances in Use of p‐H₂ as a Novel Host for Matrix IR Spectroscopy