Том 29, номер 10, статья № 13
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Аннотация:
На примере молекулы метанола показано, как средствами информационной системы W@DIS проводится систематизация ресурсов по спектроскопии. Представлены основные информационные объекты, дано объяснение выбора используемого набора квантовых чисел, кратко описаны характеристики почти 40 публикаций о поглощении метанола, и рассмотрены примеры интерфейсов для анализа согласованности волновых чисел разных источников данных, а также интерфейс приложения для формирования списка измеренных переходов.
Ключевые слова:
метанол, колебательно-вращательные переходы, информационная система W@DIS
Список литературы:
1. Rixon G., Dubernet M.L., Piskunov N., Walton N., Mason N., Le Sidaner P., Schlemmer S., Tennyson J., Akram A., Benson K., Bureau J., Doronin M., Endres C., Heiter U., Hill C., Kupka F., Nenadovic L., Marquart T., Mulas G., Ralchenko Y., Shih A., Smith K., Schmitt B., Witherick D., Boudon V., Culhane J.L., Dimitrijevic M.S., Fazliev A.Z., Joblin C., Leto G., Loboda P.A., Mason H.E., Mendoza C., Millar T.J., Nunez L.A., Perevalov V.I., Rothman L.S., Roueff E., Ryabchikova T.A., Ryabtsev A., Sahal-Brechot S., Tyuterev V.G., Wakelam V., Zeippen C.J. VAMDC – The Virtual Atomic and Molecular Data Centre – A new way to disseminate atomic and molecular data – VAMDC level 1 release // AIP Conf. Proc. 2011. V. 1344. P. 107–115.
2. Привезенцев А.И., Царьков Д.В., Фазлиев А.З. Базы знаний для описания информационных ресурсов в молекулярной спектроскопии 3. Формирование базовой и прикладной онтологии // Электронные библиотеки. 2012. Т. 15, вып. 2. URL: www.elbib.ru/index. phtml?page-elbib/ rus/journal/2012/part2/PTF
3. Voronina S.S., Privezentsev A.I., Tsarkov D V., Fazliev A.Z. An Ontological Description of States and Transitions in Quantitative Spectroscopy // Proc. SPIE. 2014. V. 9292. P. 92920C-1–92920C-10.
4. Воронина С.С., Привезенцев А.И., Царьков Д.В., Фаз-лиев А.З. Различие онтологических представлений предметной области // Труды конф. XVI Всерос. науч. конф. «Электронные библиотеки: перспективные методы и технологии». Дубна, ОИЯИ. 2014. C. 124–130.
5. Tennyson J., Bernath P.F., Brown L.R., Campargue A., Császár A.G., Daumont L., Gamache R.R., Hodges J.T., Naumenko O.V., Polyansky O.L., Rothman L.S., Vandaele A.C., Zobov N.F., Al Derzi A.R., Fabrie C., Fazliev A., Furtenbacher T., Gordon I.E., Lodi L., Mizus I. IUPAC Critical Evaluation of the Rotational-Vibrational Spectra of Water Vapor. Part III. Energy Levels and Transition Wavenumbers for H216O // J. Quant. Spectrosc. Radiat. Transfer. 2013. V. 117. P. 29–58.
6. Половцева Е.Р., Лаврентьев Н.А., Воронина С.С., Науменко О.В., Фазлиев А.З. Информационная система для решения задач молекулярной спектроскопии. 5. Колебательно-вращательные переходы и уровни энергии молекулы H2S // Оптика атмосф. и океана. 2011. Т. 24, № 10. C. 898–905; Polovtseva E.R., Lavrentiev N.A., Voronina S.S., Naumenko O.V., Fazliev A.Z. Information system for molecular spectroscopy. 5. Ro-vibrational transitions and energy levels of the hydrogen sulfide molecule // Atmos. Ocean. Opt. 2012. V. 25. N 2. P. 157–165.
7. Tennyson J., Bernath P.F., Brown L.R., Campargue A., Carleer M.R., Császár A.G., Gamache R.R., Hodges J.T., Jenouvrier A., Naumenko O.V., Polyansky O.L., Roth-man L.S., Toth R.A., Vandaele A.C., Zobov N.F., Daumont L., Furtenbacher T., Fazliev A.Z., Gordon I.E., Mikhailenko S.N., Shirin S.V. IUPAC Critical Evaluation of the Rotational-Vibrational Spectra of Water Vapor. Part I. Energy Levels and Transition Wavenumbers for H217O and H218O // J. Quant. Spectrosc. Radiat. Transfer. 2009. V. 110, N 9–10. P. 573–596.
8. Tennyson J., Bernath P.F., Brown L.R., Campargue A., Carleer M.R., Császár A.G., Daumont L., Gamache R.R., Hodges J.T., Naumenko O.V., Polyansky O.L., Rothman L.S., Toth R.A., Vandaele A.C., Zobov N.F., Fally S., Furtenbacher T., Fazliev A., Gordon I.E., Hu S.-M., Mikhailenko S.N., Voronin B.A. IUPAC Critical Evaluation of the Rotational-Vibrational Spectra of Water Vapor. Part II. Energy Levels and Transition Wavenumbers for HD16O, HD17O, and HD18O // J. Quant. Spectrosc. Radiat. Transfer. 2010. V. 111, N 15. P. 2160–2184.
9. Tennyson J., Bernath P.F., Brown L.R., Campargue A., Császár A.G., Daumont L., Gamache R.R., Hodges J.T., Naumenko O.V., Polyansky O.L., Rothman L.S., Van-daele A.C., Zobov N.F., Dénes N., Fazliev A.Z., Furtenbacher T., Gordon I.E., Hu S.-M., Szidarovszky T., Vasilenko I.A. IUPAC critical evaluation of the rotational-vibrational spectra of water vapor. Part IV. Energy levels and transition wavenumbers for D216O, D217O, and D218O // J. Quant. Spectrosc. Radiat. Transfer. 2014. V. 142. P. 93–108.
10. Ахлестин А.Ю., Воронина С.С., Науменко О.В., Половцева Е.Р., Фазлиев А.З. Информационная система для решения задач молекулярной спектроскопии. 6. Систематизация спектроскопических данных по дейтеро-замещенным изотопологам молекулы сероводорода // Оптика атмосф. и океана. 2016. Т. 29, № 5. С. 386–396.
11. Voronina S.S., Yurchenko S.N., Fazliev A.Z. Systematization of the published spectroscopic parameters of ammonia // Abstracts of the 22nd Colloquium on High Resolution Molecular Spectroscopy. 2011. P. 163.
12. Lavrentiev N.A., Privesentsev A.I., Filippov N.N., Fazliev A.Z. Complete set of published spectral data on CO2 molecule // Abstracts of the 22nd Colloquium on High Resolution Molecular Spectroscopy. 2011. P. 353.
13. Akhlestin A.Y., Voronina S.S., Privesentsev A.I., Fazliev A.Z. Systematization of published data on phosphine isotopologoues // Proc. SPIE. 2012. V. 8696. P. 8696–8738.
14. Voronina S.S., Akhlestin A.Yu., Kozodoev A.V., Lavrentiev N.A., Prevezentsev A.I., Fazliev A.Z., Naumenko O.V. Systematization of Published Spectral Data on Sulfur Dioxide Molecule and its Isotopologues // Proc. SPIE. 2014. V. 9292. P. 92920.
15. Аkhlyostin A.Yu., Voronina S.S., Lavrentiev N.A., Privezentsev A.I., Rodimova O.B., Fazliev A.Z. A systematization of spectral data on the methanol molecule // Proc. SPIE. 2015. V. 9680. P. 929208.
16. Апанович З.В., Винокуров П.С., Ахлёстин А.Ю., Привезенцев А.И., Фазлиев А.З. Цифровая библиотека научных статей по количественной спектроскопии // Труды 14-й Всерос. науч. конф. «Электронные библиотеки: перспективные методы и технологии, электронные коллекции» – RCDL’2012. Переславль, 2012. С. 53–59.
17. Быков А.Д., Науменко О.В., Синица Л.Н., Родимова О.Б., Творогов С.Д., Тонков М.В., Фазлиев А.З., Филиппов Н.Н. Информационные аспекты молекулярной спектроскопии. Томск: Изд-во ИОА СО РАН, 2008. 356 c.
18. Bykov A.D., Fazliev A.Z., Filippov N.N., Kozodoev A.V., Privezentsev A.I., Sinitsa L.N., Tonkov M.V., Tretyakov M.Yu. Distributed information system on atmospheric spectroscopy // Geophys. Res. Abstracts. 2007. V. 9. P. 01906.
19. Fazliev A., Privezentsev A., Tsarkov D., Tennyson J. Ontology-Based Content Trust Support of Expert Information Resources in Quantitative Spectroscop // Knowledge Engineering and the Semantic Web: Communications in Computer and Information Science. 2013. V. 394. P. 15–28.
20. Moruzzi G., Winnewisser B.P., Winnewisser M., Mukhopadhyay I., Strumia F. Microwave, Infrared and Laser Transitions of Methanol: Atlas of Assigned Lines from 0 to 1258 cm–1. Boca Raton; New York; London; Tokyo: CRC Press, 1995. 544 p.
21. Rothman L.S., Gordon I.E., Barbe A., Benner D.C., Bernath P.F., Birk M., Boudon V., Brown L.R., Campargue A., Champion J.-P., Chance K., Coudert L.H., Dana V., Devi V.M., Fally S., Flaud J.-M., Gamache R.R., Goldman A., Jacquemart D., Kleiner I., Lacome N., Lafferty W.J., Mandin J.-Y., Massie S.T., Mikhailenko S.N., Miller C.E., Moazzen-Ahmadi N., Naumenko O.V., Nikitin A.V., Orphal J., Perevalov V.I., Perrin A., Predoi-Cross A., Rinsland C.P., Rotger M., Simeckova M., Smith M.A.H., Sung K., Tashkun S.A., Tennyson J., Toth R.A., Vandaele A.C., Auwera J.V. The HITRAN 2008 molecular spectroscopic database // J. Quant. Spectrosc. Radiat. Transfer. 2009. V. 110, N 9. P. 533–572.
22. Jacquinet-Husson N., Crepeau L., Armante R., Boutammine C., Chédin A., Scott N.A., Crevoisier C., Capelle V., Boone C., Poulet-Crovisier N., Barbe A., Campargue A., Chris Benner D., Benilan Y., Bézard B., Boudon V., Brown L.R., Coudert L.H., Cous-tenis A., Dana V., Devi V.M., Fally S., Fayt A., Flaud J.-M., Goldman A., Herman M., Harris G.J., Jacquemart D., Jolly A., Kleiner I., Kleinböhl A., Kwabia-Tchana F., Lavrentieva N., Lacome N., Xu L.-H., Lyulin O.M., Mandin J.-Y., Maki A., Mikhailenko S., Miller C.E., Mishina T., Moazzen-Ahmadi N., Müller H.S.P., Nikitin A., Orphal J., Perevalov V., Per-rin A., Petkie D.T., Predoi-Cross A., Rinsland C.P., Remedios J.J., Rotger M., Smith M.A.H., Sung K., Tennyson J., Toth R.A., Vandaele A.-C., Vander Auwera J. The 2009 edition of the GEISA spectroscopic database // J. Quant. Spectrosc. Radiat. Transfer. 2011. V. 112, N 15. P. 2395–2445.
23. Longuet-Higgins H.C. The symmetry groups of non-rigid molecules // Mol. Phys. 1963. V. 6, N 5. P. 445–460.
24. Bunker P.R. Molecular symmetry and spectroscopy. New York; San Fracisco; London: Academic Press, 1979. 169 p.
25. Frei H., Bauder A., Gunthard H.H. The isometric group of nonrigid molecules // Large amplitude motion in molecules. Berlin; New York: Springer-Verlag, 1979. V. 1. P. 1–97.
26. Altmann S.L. The symmetry of nonrigid molecules: The Schrodinger supergroup // Proc. Roy. Soc. A. London, 1967. V. 298. P. 184–203.
27. Altmann S.L. More on the symmetry of non-rigid molecules // Mol. Phys. 1971. V. 21, N 4. P. 587–607.
28. Smeyers Y.G. Introduction to Group Theory for Non-Rigid Molecules // Adv. Quant. Chem. 1992. V. 24, N 1. P. 1–77.
29. Буренин А.В. Концепция цепочки групп симметрии в теории спектров молекул // Успехи физ. наук. 1993. Т. 163, № 3. С. 87–98.
30. Буренин А.В. Симметрия квантовой внутримолекулярной динамики. Н.Новгород: ИПФ РАН, 2012. 416 с.
31. Буренин А.В. Конфигурационное вырождение обменного типа в колебательно-вращательном спектре нежесткой молекулы // Ж. структ. химии. 1995. Т. 36, № 1. С. 9–15
32. Буренин А.В. Новый взгляд на картину торсионного движения в молекуле метанола СН3ОН // Оптика и спектроскопия. 1998. Т. 85, № 6. С. 942–947
33. Koehler J.S., Dennison D.M. Hindered Rotation in Methyl Alcohol // Phys. Rev. 1940. V. 57. P. 1006–1021.
34. Lees R.M., Xu Li-Hong, Johns J.W.C., Winnewisser B.P., Lock M. Rotation-torsion-vibration term-value mapping for CH3OH: Torsion-mediated doorways and corridors for intermode population transfer // J. Mol. Spectrosc. 2007. V. 243, N 2. P. 168–181.
35. Pearson J.C., Drouin B.J., Yu S., Gupta H. Microwave spectroscopy of methanol between 2.48 and 2.77 THz // J. Opt. Soc. Amer. B. 2011. V. 28, N 10. P. 2549–2577.
36. Lees R.M. Torsion-Vibration-Rotation Interactions in Methanol. III. Barrier Height in an Excited Vibrational State of CH3OH // J. Chem. Phys. 1972. V. 57, N 2. P. 824–826.
371. Kwan Y.Y., Dennison D.M. Analysis of the torsion-rotation spectra of the isotopic methanol molecules // J. Mol. Spectr. 1972. V. 43, N 2. P. 291–319.
38. Lees R.M. Torsion-Vibration-Rotation Interactions in Methanol. IV. Microwave Spectrum of CH3OH in the Excited CO Stretching State // J. Chem. Phys. 1972. V. 57, N 6. P. 2249–2252.
39. Radford H.E. Remeasurement of the Rest Frequency of the 36-Centimeter Radio Line of Methanol // Astrophys. J. 1972. V. 174. P. 207–208.
40. Stern V., Belorgeot C., Kachmarsky J., Moller K.D. Far infrared spectrum of the internal rotation of CH3OH and CD3OH // J. Mol. Spectrosc. 1977. V. 67, N 1–3. P. 244–264.
41. Bedwell D.J., Duxbury G., Herman H., Orengo C.A. Laser Stark and optical-optical double resonance studies of some molecules used in optically pumped submillimetre lasers // Infrared Phys. 1978. V. 18, N 5–6. P. 453–460.
42. Sakai М., Ichimura K., Masumoto H., Kitagawa Y. High-resolution spectroscopy of some gaseous molecules with a submillimetre Fourier transform spectrometer // Infrared Phys. 1978. V. 18, N 5–6. P. 577–583.
43. Worchesky T.L. Assignment of methyl alcohol submillimeter laser transitions // Opt. Lett. 1978. V. 3, N 6. P. 232–234.
44. Sattler J.P., Riessler W.A., Worchesky T.L. Diode laser spectra of the C–O stretch band of gaseous methyl alcohol // Infrared Phys. 1979. V. 19, N 2. P. 217–224.
45. Lovas F.J., Suenram R.D., Snyder L.E., Hollis J.M., Lees R.M. Detection of the torsionally excited state of methanol in Orion A // Astrophys. J. 1982. V. 253, N 1. P. 149–153.
46. Bernard P., Izatt J.R. New CH3OH Laser Lines pumped with a Fine-Tuned High-Power CO2-TEA Laser // Int. J. Infrared Millim. Waves. 1983. V. 4, N 1. P. 21–35.
47. Brink G.O. Absorption spectrum of the fourth overtone of the OH stretch in gaseous methanol // J. Mol. Spectrosc. 1984. V. 103, N 2. P. 295–299.
48. Sastry K.V.L.N., Lees R.M., De Lucia F.C. Microwave and submillimeter-wave spectra of CH3OH // J. Mol. Spectrosc. 1984. V. 103, N 2. P. 486–494.
49. Lees R.M., Mukhopadhyay I., Johns J.W.C. Assignment of IR transitions and FIR laser lines from torsionally excited CH3OH // Opt. Commun. 1985. V. 55, N 2. P. 127–130.
50. Rudolph H., Avery J., Henningsen J.O. Torsion-vibration interaction in CH3OH // J. Mol. Spectrosc. 1986. V. 117, N 1. P. 38–45.
51. Lees R.M. Far Infrared (FIR) and Infrared (IR) Spectroscopy of Methanol Applied to FIR Laser Assignments // Proc. SPIE. 1986. V. 666. P. 158–170.
52. Mukhopadhyay I., Lees R.M., Johns J.W.C. Torsional refilling transitions in tea-pumped CH3OH fir lasers with associated high-resolution fir spectra // Int. J. Infrared Millim. Waves. 1987. V. 8, N 11. P. 1471–1482.
53. Mukhopadhyay I., Lees R.M., Johns J.W.C. Confirmation of far infrared laser assignments from CH3-deformation and CH3-rocking states of optically pumped methanol // Appl. Phys. B: Lasers Opt. 1988. V. 47, N 4. P. 319–324.
54. Moruzzi G., Strumia F., Carnesecchi P., Lees R.M., Mukhopadhyay I., Johns J.W.C. Fourier spectrum of CH3OH between 950 and 1100 cm–1 // Infrared Phys. 1989. V. 29, N 2–4. P. 583–606.
55. Moruzzi G., Prevedelli M., Evenson K.M., Jennings D.A., Vanek M.D., Inguscio M. Ultrahigh resolution far-infrared spectroscopy of methanol // Infrared Phys. 1989. V. 29, N 2–4. P. 541–549.
56. Inguscio M., Zink L.R., Evenson K.M., Jennings D.A. Accurate Frequency of the 119 μm Methanol Laser from Tunable Far-Infrared Absorption Spectroscopy // IEEE J. Quant. Electron. 1990. V. 26, N 3. P. 575–579.
57. Carelli N., Ioli N., Moretti A., Pereira D., Strumia F. Acoustooptic Extension of the Frequency tunability of cw CO2 Lasers: New FIR laser Emissions from CH3OH and 13CH3OH // Int. J. Infrared Millim. Waves. 1991. V. 12, N 5. P. 449–471.
58. Hunt R.H., Shelton W.N., Cook W.B., Bignall O.N., Mirick J.W., Flaherty F.A. Torsion-rotation absorption line assignments in the symmetric CH-stretch fundamental of methanol // J. Mol. Spectrosc. 1991. V. 149, N 1. P. 252–256.
59. Mukhopadhyay I., Lees R.M., Johns J.W.C. Assignments and predictions of far-infrared laser lines in methyl alcohol // Opt. Commun. 1991. V. 80, N 5–6. P. 425–434.
60. Anderson T., Herbst E., De Lucia F.C. An extension of the high-resolution millimeter- and submillimeter-wave spectrum of methanol to high angular momentum quantum numbers // Astrophys. J. Suppl. Series. 1992. V. 82. P. 405–444.
61. Goulding R.R.J., Mukhopadhyay I., Lees R.M. Infrared-infrared double resonance study of methyl alcohol // Infrared Phys. 1992. V. 33, N 5. P. 443–447.
62. Moruzzi G., Strumia F., Moraes J.C.S., Lees R.M., Mukhopadhyay I., Johns J.W.C., Winnewisser B.P., Winnewisser M. The spectrum of CH3OH between 200 and 350 cm–1: Torsional transitions and evidence for state mixings // J. Mol. Spectrosc. 1992. V. 153, N 1–2. P. 511–577.
63. Hepp M., Pak I., Yamada K.M.T., Herbst E., Winnewisser G. Diode Laser Study of the Rotational Redistribution in CH3OH during a Supersonic Jet Expansion // J. Mol. Spectrosc. 1994. V. 166, N 1. P. 66–78.
64. Odashima H., Matsushima F., Nagai K., Tsunekawa S., Takagi K. Far-Infrared Spectroscopy of Methanol Using a Tunable Coherent Radiation Source // J. Mol. Spectrosc. 1995. V. 173, N 2. P. 404–422.
65. Xu L.-H., Wang X., Cronin T.J., Perry D.S., Fraser G.T., Pine A.S. Sub-Doppler Infrared Spectra and Torsion–Rotation Energy Manifold of Methanol in the CH-Stretch Fundamental Region // J. Mol. Spectrosc. 1997. V. 185, N 1. P. 158–172.
66. Schilke P., Benford D.J., Hunter T.R., Lis D.C., Philips T.G. A line survery of Orion-KL from 607 to 725 GHz // Astrophys. J. Suppl. Ser. 2001. V. 132. P. 281–364.
67. Brooke T.Y., Weaver H.A, Chin G., Bockelee-Morvan D., Kim S.J., Xu L.-H. Spectroscopy of Comet Hale–Bopp in the infrared // Icarus. 2003. V. 166, N 1. P. 167–187.
68. Xu S., Kay J.J., Perry D.S. Doppler-limited CW infrared cavity ringdown spectroscopy of the n1+ n3 OH + CH stretch combination band of jet-cooled methanol // J. Mol. Spectrosc. 2004. V. 225, N 2. P. 162–173.
69. Mukhopadhyay I., Ozier I., Lees R.M. High-Resolution Spectrum of the C–O Stretch Overtone Band in Methyl Alcohol // J. Chem. Phys. 2010. V. 93, N 10. P. 7049–7053.
70. Slocum D.M., Xu L.-H., Giles R.H., Goyette T.M. Retrieval of methanol absorption parameters at Terahertz frequencies using multispectral fitting // J. Mol. Spectrosc. 2015. V. 318. P. 12–25.
71. Votava O., Horka-Zelenkova V., Svoboda V., Rakovsky J., Pracna P. OH-stretch overtone of methanol: empirical assignment using two temperature technique in supersonic jet // Phys. Chem. Chem. Phys. 2015. V. 17. P. 15710–15717.
72. Ахлестин А.Ю., Козодоев А.В., Лаврентьев Н.А., Привезенцев А.И., Фазлиев А.З. Базы знаний для описания информационных ресурсов в молекулярной спектроскопии. 4. Программное обеспечение ИВС «Молекулярная спектроскопия» // Электронные библиотеки. 2012. Т. 15, № 3. URL: www.elbib.ru/ index. phtml?page-elbib/rus/journal/2012/part3/AKLPF
73. Ахлестин А.Ю., Лаврентьев Н.А., Привезенцев А.И., Фазлиев А.З. Базы знаний для описания информационных ресурсов в молекулярной спектроскопии. 5. Качество экспертных данных // Электронные библиотеки. 2013. Т. 16, № 4. URL: www.elbib.ru/index. phtml?page-elbib/rus/journal/2013/ part4/AKLPF
74. Moruzzi G., Strumia F., Carnesecchi P., Carli B., Carlotti M. High resolution spectrum of CH3OH between 8 and 100 cm–1// Infrared Phys. 1989. V. 29, N 1. P. 47–86.
75. Moruzzi G., Riminucci P., Strumia F., Carli B., Carlotti M., Lees R.M., Mukhopadhyay I., Johns J.W.C., Winnewisser B.P., Winnewisser M. The spectrum of CH3OH between 100 and 200 cm–1: Torsional and “forbidden” transitions // J. Mol. Spectrosc. 1990. V. 144, N 1. P. 139–200.
76. Pearson J.C., Drouin B.J., Yu S., Gupta H. Microwave spectroscopy of methanol between 2.48 and 2.77 THz // J. Opt. Soc. Amer. B. 2011. V. 28. P. 2549–2577.
77. Lees R.M., Lovas F.J., Kirchhoff W.H., Johnson D.R. Microwave Spectra of Molecules of Astrophysical Interest: III. Methanol // J. Phys. Chem. Ref. Data. 1973. V. 2, N 2. P. 205–214.
78. Gaines L., Casleton K.H., Kukolich S.G. Beam Maser Measurements of CH3OH Rotational Transitions // Astrophys. J. 1974. V. 191, N 7. P. L99–L100.
79. Pickett H.M., Cohen E.A., Brinza D.E., Schaefer M.M. The submillimeter wavelength spectrum of methanol // Int. J. Infrared Millimeter Waves. 1981. V. 89, N 2. P. 542–547.
80. Moruzzi G., Strumia F., Bonetti C., Carli B., Mencaraglia F., Carlotti M., Di Lonardo G., Trombetti A. The Fourier spectrum of CH3OH: The region between 8 and 40 cm–1 // J. Mol. Spectrosc. 1984. V. 105, N 1. P. 24–52.
81. Coudert L., Valentin A. The rotation-torsion energy levels of the methanol molecule 12CH316OH above the triple potential barrier // J. Mol. Spectrosc. 1987. V. 122, N 2. P. 390–407.
82. Zink L.R., Evenson K.M., Jennings D.A., Moruzzi G., Inguscio M. Frequency measurement of the K = 6 asymmetry splittings in CH3OH // J. Mol. Spectrosc. 1988. V. 127, N 1. P. 44–50.
83. De Lucia F.C., Herbst E., Anderson T. The analysis of the rotational spectrum of methanol to microwave accuracy // J. Mol. Spectrosc. 1989. V. 134, N 2. P. 395–411.
84. Dang-Nhu M., Blanquet G., Walrand J., Allegrini M., Moruzzi G. Intensities of the CO stretch band of CH3OH at 9.7 µm // J. Mol. Spectrosc. 1990. V. 141, N 2. P. 348–350.
85. Mukhopadhyay I., Lees R.M., Sastry K.V.L.N. Detection of weak microwave and millimeter wave transitions in the C–O stretch state of methyl alcohol // Infrared Phys. 1990. V. 30, N 3. P. 291–293.
86. Mukhopadhyay I., Ozier I., Lees R.M. High-resolution spectrum of the C–O stretch overtone band in methyl alcohol // J. Chem. Phys 1990. V. 93, N 10. P. 7049–7053.
87. Dang-Nhu M., Blanquet G., Walrand J. Intensities of methanol spectra around 12.5 µm // J. Mol. Spectrosc. 1991. V. 146, N 2. P. 524–526.
88. Baskakov O.I., Pashaev M.A.O. Microwave and submillimeter-wave rotational spectrum of methyl alcohol in the ground torsional state // J. Mol. Spectrosc. 1992. V. 151, N 2. P. 282–291.
89. Matsushima F., Evenson K.M., Zink L.R. Absolute Frequency Measurements of Methanol from 1.5 to 6.5 THz // J. Mol. Spectrosc. 1994. V. 164, N 2. P. 517–530.
90. Belov М., Winnewisser G., Herbst E. The High-Resolution Rotational-Torsional Spectrum of Methanol from 0.55 to 1.2 THz // J. Mol. Spectrosc. 1995. V. 174, N 1. P. 253–269.
91. Breckenridge S.M., Kukolich S.G. Precise laboratory measurements of methanol rotational transition frequencies in the 5 to 13 GHz region // Astrophys. J. 1995. V. 438, N 1. P. 504–505.
92. Xu L.H., Hougen J.T. Global Fit of Torsional-Rotational Transitions in the Ground and First Excited Torsional States of Methanol // J. Mol. Spectrosc. 1995. V. 173, N 2. P. 540–551.
93. Xu L.H., Hougen J.T. Global Fit of Rotational Transitions in the Ground Torsional State of Methanol // J. Mol. Spectrosc. 1995. V. 169, N 2. P. 396–409.
94. Sun Z.-D., Matsushima F., Tsunekawa S., Takagi K. Sub-Doppler spectroscopy of the CO stretching fundamental band of methanol by use of microwave sidebands of CO2 laser lines // J. Opt. Soc. Amer. B. 2000. V. 17, N 12. P. 2068–2080
95. Rueda D., Boyarkin O.V., Rizzo T.R., Mukhopadhyay I., Perry D.S. Torsion-rotation analysis of OH stretch overtone–torsion combination bands in methanol // J. Chem. Phys 2002. V. 116, N 1. P. 91–100.
96. Lees R.M., Xu L.-H., Johns J.W.C., Winnewisser B.P., Lock M. Rotation-torsion-vibration term-value mapping for CH3OH: Torsion-mediated doorways and corridors for intermode population transfer // J. Mol. Spectrosc. 2007. V. 243, N 2. P. 168–181.
97. Brauer C.S., Sung K., Pearson J.C., Brown L.R., Xu L.-H. Empirical line intensities of methanol in the 300–500 cm–1 region // J. Quant. Spectrosc. Radiat. Transfer. 2012. V. 113, N 2. P. 128–139.
98. Tsarkov D., Horrocks I. FaCT++ description logic reasoner: System description // Proc. 3rd Int. Joint Conf. on Automated Reasoning (IJCAR’06). LNCS: Springer, 2006. V. 4130. P. 292–297.