References for the GEISA 2011 sub-database on absorption cross-sections : IR

Molecules list : SF₅CF₃, C₆H₆, CH₃CN, C₂H₃NO₅, (CH₃)₂CO

SF₅CF₃ (Trifluoromethyl sulphur pentafluoride)
SF₅CF₃ IR absorption cross-sections from M. Hurley were implemented in GEISA 2003. The absorption cross-sections measured by Rinsland et al. [1], at five temperatures between 213 and 323 K in the infrared bands of SF₅CF₃ are newly added to GEISA 2011. The spectra were recorded at a resolution of 0.112 cm^-1 using a commercial Fourier transform infrared spectrometer and a 20 cm temperature-controlled sample cell. The full spectral range of the measurements was 520–6500 cm^-1, with only weak bands observed beyond 1400 cm^-1. Absorption of thermal radiation in the 8–12 μm atmospheric window region being important for climate change, the measured integrated cross-sections of the significant absorption bands in that spectral region have been added to the GEISA archive. It has to be noted that the SF₅CF₃ atmospheric growth has closely paralleled the rise of SF₆ during the past three decades, with an estimated radiative forcing of 0.57 W m^-2 ppb^-1, slightly higher than for SF₆ [2].

References :
[1] Rinsland CP, Sharpe SW, Sams RL. Temperature-dependent cross-sections in the thermal infrared bands of SF₅CF₃. JQSRT 2003;82:483–90.
[2] Scientific assessment of ozone depletion, 1988. Global ozone research and monitoring project, report 44, World Meteorological Organization, Geneva, 1999.


C₆H₆ (Benzene)
Integrated band intensities of benzene at temperatures of 278, 298, and 323 K, in the spectral range 600-6500 cm^-1 by Rinsland et al. [1], have been added to GEISA 2011 IR cross-sections archive. These data derived from pressure broadened (1 atm N2) laboratory spectra of benzene vapor (in natural abundance) recorded at PNNL with a 0.112 cm^-1 resolution Bruker-66 V Fourier transform spectrometer configured to operate in the mid-infrared. Using very high precision capacitance nanometers, over nine sample pressures were recorded for each of the three temperatures. Hard-mounted into the spectrometer, a temperature-stabilized static cell (19.94(1) cm path-length), was used for support of the samples introduced into it. Two- hundred fifty-six interferograms were averaged for each sample spectrum. A composite spectrum was calculated for each cell temperature from the individual absorbance spectra recorded at that temperature. The average uncertainty (NIST type-A) is respectively: 0.40%, 0.38% and 0.54% for the 278 K, 298 K, and 323 K spectra. The number density for the three composite spectra was normalized to 296 K. The spectra give the absorption IR cross-sections (cm² molecule^-1, naperian units) of benzene as a function of wavenumber

Reference :
[1] Rinsland CP, Devi VM, Blake TA, Sams RL, Sharpe S, Chiou LS. Quantitative measurement of integrated band intensities of benzene vapor in the mid-infrared at 278, 298, and 323 K. JQSRT 2008;109:2511-22.


CH₃CN (Acetonitrile, -Methyl cyanide)
Infrared cross sections were measured at the Pacific Northwest National Laboratory by Rinsland et al. [1]. These 29 spectra covered 600 and 6500 cm^-1 with a resolution of 0.1125 cm^-1 and were measured at three different temperatures (276 K, 299 K, and 324 K). They were recorded with different CH₃CN volume mixing ratios at 1 atm pressure using N₂ as pressure broadening gas. The CH₃CN cross-sections of Ref. [2] have been derived at three temperatures: 276.1 K, 298.7 K and 324.1 K, in six spectral ranges from 635 to 4574 cm^-1 and 1 atm N₂ pressure broadened vapour.

References :
[1] Rinsland CP, Devi VM., Benner DC, Blake TA, Sams RL, Brown LR, et al. Multispectrum analysis of the ν4 band of CH₃CN: Positions, intensities, self- and N2-broadening and pressure-induced shifts. JQSRT 2008;109:974-94.
[2] Rinsland CP, Sharpe SW, Sams RL. Temperature-dependent infrared absorption cross sections of methyl cyanide (acetonitrile). JQSRT 2005;96:271-80.


C₂H₃NO₅ (PeroxyAcetyl Nitrate, -PAN)
New spectroscopic data for PAN, in the form of cross-sections, have therefore been included in the GEISA database for the first time, based on the measurements of Allen et al. [1,2]. The cross-sections cover the spectral range between 560 cm^-1 and 1400 cm^-1 at three temperature (295 K, 273 K, 250 K), and between 1686 cm^-1 and 2000 cm^-1 at two temperatures (295 K and 250 K). The data include all bands from ν4 to ν19, except for ν16 centred at 1653 cm^-1 which is detected in the original measurements at 295 K but is not included here because of weakness of the band and residual water vapour contamination. The band assignments are based on those reported in Gaffney et al. [3] and Bruckmann and Wilner [4]. The five main bands are ν4, ν5, ν9, ν10 and ν16 centred at 1842, 1741, 1302, 1161.5 and 791.5 cm^-1 respectively; a small shift of 1 cm^-1 was observed in the peak of the ν4 band at 1842 cm^-1 with temperature [2]. Uncertainties in the cross-sections were estimated to be 5% at 250 K [2] rising to 7% at 295 K [1].

References :
[1] Allen G, Remedios JJ, Newnham DA, Smith KM, Monks PS. Improved mid-infrared cross-sections for peroxyacetylnitrate (PAN) vapour. Atmos Chem Phys 2005;5:47–56.
[2] Allen G, Remedios JJ, Smith KM. Low temperature mid-infrared cross-sections for peroxyacetyl nitrate (PAN) vapour. Atmos Chem Phys 2005;5:3153–8.
[3] Gaffney JS, Fajer R, Senum GI. An improved procedure for high purity gaseous peroxyacetyl nitrate production: Use of heavy lipid solvents. Atmos. Envir 1984;18:215–8.
[4] Bruckmann PW, Willner H. Infrared spectroscopic study of peroxyacetyl nitrate (PAN) and its decomposition products. Envir Sci Tech 1983;17:352–7.


(CH₃)₂CO (Acetone)
New spectroscopic data for acetone, in the form of cross-sections, have been included in the GEISA database for the first time, based on the measurements of Waterfall [1]. The cross-sections at spectral resolution of 0.03 cm^-1 cover the spectral range between 600 cm^-1 and 1800 cm^-1 around six temperature series (214, 223, 233, 253, 272, 297 K); see Table 10 for precise details. The data include the ν18 band centred at 830 cm^-1, the ν17 at 1218 cm-1, the ν16/ν5 bands close to 1360 cm^-1 overlapping with the unresolved bands of ν15, ν4 and ν21 centred between 1430 and 1460 cm-1, and the ν3 band centred at 1738 cm^-1; band assignments are taken from Wang et al. [2]. The ν7 band, centred at 777 cm^-1, and the ν22/ν6 near 1093 cm-1 are only very weakly present in the measured cross-sections. The main cross-section influence is for the strongest bands observed between 1200 and 1800 cm^-1 for which uncertainties range from 5% (7% for the centre of the ν3, 1738 cm^-1 band) at the strongest parts of the band to 10% towards the edges. For the 830 cm^-1 band, errors are approximately 12% at band centre rising to greater than 20% at the band edges.

References :
[1] Waterfall A. Measurement of organic compounds in the upper troposphere. Ph. D. Thesis, University of Oxford, 2003.
[2] Wang WF, Stevenson A, Reuter DC, Sirota JM. Absolute band intensities in of acetone (CH₃)₂CO in the infrared region of 830-3200 cm^-1 at low and room temperatures. Spectrochim Acta Part A 2001;57:1603-10.