Реакции радиационно-индуцированных избыточных электронов с молекулами карбонильных соединений в низкотемпературных матрицах, страница 25
Описание файла
PDF-файл из архива "Реакции радиационно-индуцированных избыточных электронов с молекулами карбонильных соединений в низкотемпературных матрицах", который расположен в категории "". Всё это находится в предмете "химия" из Аспирантура и докторантура, которые можно найти в файловом архиве МГУ им. Ломоносова. Не смотря на прямую связь этого архива с МГУ им. Ломоносова, его также можно найти и в других разделах. , а ещё этот архив представляет собой кандидатскую диссертацию, поэтому ещё представлен в разделе всех диссертаций на соискание учёной степени кандидата химических наук.
Просмотр PDF-файла онлайн
Текст 25 страницы из PDF
Am. Chem.Soc. – 1968. – V.90. – N. 11. – P. 2766-2774.47. Баранова И.А., Фельдман В.И., Белевский В.Н. Электронные процессы прирадиолизе диэтилового эфира при 77 К // Хим. Выс. Энерг. – 1986. – № 20. – С. 387391.48. Yoshida H., Feng D.-F., Kevan L. Electron-electron double resonance study oftrapped electrons in γ-irradiated 2-methyltetrahydrofuran glass: magnetic energy transferbetween two different spin systems // J. Chem. Phys.
– 1973. – V.58. – N. 11. – P. 49244929.49. Marshall E.J., Pilling M.J., Rice S.A. Electron tunneling in glassy media. γRadiolysis investigation of electron scavenging in methanol, 2-methyltetrahydrofuran and10-3 mol dm-3 hydroxide glasses at 77 K // J. Chem. Soc. Faraday Trans. 2. – 1975. – V. 71.– P. 1555-1562.50. Баранова И.А.
Ионные процессы при радиолизе простых эфиров : дис. …канд. хим. наук : 02.00.09 / Баранова Ирина Александровна. – М., 1988. – 196 с.16851. Shida T., Iwata S., Watanabe T. Electronic absorption spectra of excess electronsin molecular aggregates. I. Trapped electrons in γ-irradiated amorphous solids at 770K // J.Phys. Chem.
– 1972. – V.76. – N. 25. – P. 3683-3691.52. ЭПР свободных радикалов в радиационной химии / Пшежецкий С.Я., КотовА.Г., Милинчук В.К., Рогинский В.А., Тупиков В.И. М.: Химия, 1972. – 480 с.53. Пикаев А.К., Бродский А.М. Физико-химия электрона в конденсированнойсреде // Хим. Выс. Энерг. – 1972. – Т. 6. – N. 2. – С. 224-229.54. Сольватированный электрон в радиационной химии / Пикаев А.К.
М.:Наука, 1969. – 457 с.55. Avery E.C., Remko J.R., Smaller B. EPR detection of the hydrated electron inliquid water // J. Chem. Phys. – 1968. – V. 49. – N. 2. – P. 951.56. Электронное спиновое эхо и его применение / Салихов К.М., Семенов А.Г.,Цветков Ю.Д. Новосибирск: Наука, 1976. – 342 с.57. Narayana P.A., Bowman M.K., Kevan L., Yudanov V.F., Tsvetkov Y.D. Electronspin echo envelope modulation of trapped radicals in disordered glassy systems:Application to the molecular structure around excess electrons in γ‐irradiated 10M sodiumhydroxide alkaline ice glass // J.
Chem. Phys. – 1975. – V. 63. – N. 8. – P. 3365-3371.58. Kevan L. Electron-spin echo studies of solvation structure // J. Phys. Chem. –1981. – V. 85. – N. 12. – P. 1628-1636.59. Kevan L. Solvated electron structure in glassy matrices // Acc. Chem. Res. –1981. – V. 14. – N. 5. – P. 138-145.60. Natori M., Watanabe T. Structural model of hydrated electron // J. Phys. Soc. Jpn.– 1966. – V. 21. – N. 8. – P. 1573-1578.61. Natori M. Structural model of the hydrated electron. II // J. Phys.
Soc. Jpn. –1968. – V. 24. – N. 4. – P. 913-916.62. Natori M. Structural model of the hydrated electron. III // J. Phys. Soc. Jpn. –1969. – V. 27. – N. 5. – P. 1309-1319.16963. Shkrob I.A. The structure of the hydrated electron. Part 1. Magnetic resonance ofinternally trapping water anions: a density functional theory study // J. Phys. Chem. A.
–2007. – Vol. 111. – N. 24. – P. 5223-5231.64. Shkrob I.A., Glover W.J., Larsen R.E., Schwartz B.J. The structure of thehydrated electron. Part 2. A mixed quantum/classical molecular dynamics embeddedcluster density functional theory: single-excitation configuration interaction study // J.Phys. Chem. A. – 2007. – Vol. 111. – N. 24. –P. 5232-5243.65. Christophorou L.G., Blaunstein R.P. Electron attachment in gases and liquids //Chem. Phys.
Lett. – 1971. – V. 12. – N. 1. – P. 173-179.66. Vannikov A.V. The solvated electron in polar organic liquids // Russ. Chem. Rev.– 1975. – V. 44. – N. 11. – P. 906-912.67. Coe J.V., Lee G.H., Eaton J.G., Arnold S.T., Sarkas H.W., Bowen K.H., LudewigtC., Haberland H., Worsnop D.R.
Photoelectron-Spectroscopy of Hydrated Electron ClusterAnions, (H2O)n = 2-69 // J. Chem. Phys. – 1990. – V. 92. – N. 6. – P. 3980–3982.68. Hammer N.I., Shin J.W., Headrick J.M., Diken E. G., Roscioli J.R., Weddle G.H.,Johnson M.A. How do small water clusters bind an excess electron? // Science. – 2004. –V. 306. – N. 5696. – P. 675–679.69. Verlet J.R.R., Bragg A.E., Kammrath A., Cheshnovsky O., Neumark D.M.Observation of large water-cluster anions with surface-bound excess electrons // Science. –2005. – V. 307. – N. 5706. – P. 93–96.70.
Ma L., Majer K., Chirot F., von Issendorff B. Low temperature photoelectronspectra of water cluster anions // J. Chem. Phys. – 2009. – V. 131. – N. 14. – P. 144303(16).71. Sommerfeld T., Jordan K.D. Electron binding motifs of (H2O)n- clusters // J. Am.Chem. Soc. – 2006. – V. 128. –N. 17. – P. 5828–5833.72.
Siefermann K.R., Liu Y.X., Lugovoy E., Link O., Faubel M., Buck U., Winter B.,Abel B. // Binding energies, lifetimes and implications of bulk and interface solvatedelectrons in water // Nat. Chem. – 2010. – V. 2. – N. 4. - 274–279.17073. Shreve A.T., Yen T.A., Neumark D.M. Photoelectron spectroscopy of hydratedelectrons // Chem. Phys. Lett. – 2010. – V. 493. – N. 4-6. – P. 216–219.74. Tang Y., Shen H., Sekiguchi K., Kurahashi N., Mizuno T., Suzuki Y.I., Suzuki T.Direct measurement of vertical binding energy of a hydrated electron // Phys.
Chem.Chem. Phys. – 2010. – V. 12. – N. 15. – P. 3653–3655.75. Sagar D.M., Bain C.D., Verlet J.R.R. Hydrated electrons at the water/air interface// J. Am. Chem. Soc. – 2010. – V. 132. – N. 20. – P. 6917–6919.76. Marsalek O., Uhlig F., Frigato T., Schmidt B., Jungwirth P.
Dynamics of electronlocalization in warm versus cold water clusters // Phys. Rev. Lett. – 2010. – V. 105. – N. 4.– P. 043002(1-4).77. Marsalek O., Uhlig F., Jungwirth P. Electrons in cold water clusters: an ab initiomolecular dynamics study of localization and metastable states // J. Phys. Chem. C. –2010. V. 114. – N. 48. – P. 20489–20495.78. Sauer M.C., Arai S., Dorfman L.M.
Pulse radiolysis studies. VII. The absorptionspectra and radiation chemical yields of the solvated electron in the aliphatic alcohols // J.Chem. Phys. – 1965. – V. 42. – N. 2. – P. 708-712.79. Hentz R.R., Kenney-Wallace G. Optical-absorption of solvated electrons inalcohols and their mixtures with alkanes // J. Phys. Chem. – 1972. – V.
76. – N. 20. – P.2931-2133.80. Hentz R. R., Kenney-Wallace G. Influence of molecular-structure on opticalabsorption spectra of solvated electrons in alcohols // J. Phys. Chem. – 1974. – V. 78. – N.5. – P. 514-519.81. Arai S., Sauer M.C. Absorption spectra of solvated electron in polar liquids dependence on temperature and composition of mixtures // J.
Chem. Phys. – 1966. – V. 44.– N. 6. – P. 2297-2305.82. Dorfman L.M., DeBacker M.G., Dye J.L. Pulse radiolysis studies. XVIII.Spectrum of the solvated electron in the systems ethylenediamine–water and ammonia–water // J.Chem. Phys. – 1970. – V. 52. – N. 12. – P. 6251-6258.17183.
Ottolenghi M., Bar -Eli K., Linschitz H., Tuttle T.R. Species present inalkali‐metal amine solutions // J. Chem. Phys. – 1964. – V. 40. – N. 12. – P. 3729-3730.84. Jha K.N., Bolton G.L., Freeman G.R. Temperature shifts in the optical spectra ofsolvated electrons in methanol and ethanol // J. Phys. Chem. – 1972. – V. 76. – N. 25. – P.3876-3883.85. Freeman G.R. Solvent structure dependence of the optical excitation energy ofsolvated electrons // J. Phys. Chem.
– 1973. – V. 77. – N. 1. – P. 7-9.86. Gavlas J.F., Jou F.Y., Dorfman L.M. Optical absorption spectrum of the solvatedelectron in some liquid amides and amines // J. Phys. Chem. – 1974. – V. 78. – N. 25. – P.2631-2635.87. Jacobson L.D., Williams C.F., Herbert J.M. The static-exchange electron-waterpseudopotential, inconjunction with a polarizable water model: A new Hamiltonian forhydrated-electron simulations // J.
Chem. Phys. – 2009. – V. 130. – N. 12 – P. 124115(118).88. Jacobson L.D., Herbert J.M. A one-electron model for the aqueous electron thatincludes many-body electron-water polarization: Bulk equilibrium structure, verticalelectron binding energy, and optical absorption spectrum // Chem. Phys. – 2010.
– V. 133.– N. 15. –P. 154506(1-19).89. Schnitker J., Rossky P.J. Quantum simulation study of the hydrated electron // J.Chem. Phys. – 1987. – V. 86. – N. 6. – P. 3471-3485.90. Wallqvist A., Thirumalai D., Berne B.J. Path integral Monte Carlo study of thehydrated electron // J. Chem. Phys. – 1987. – V. 86. – N. 11. – P. 6404-6418.91. Romero C., Jonah C.D. Molecular dynamics simulation of the optical absorptionspectrum of the hydrated electron // J. Chem. Phys. – 1989. – V. 90. – N.
3. – P. 18771887.92. Miura S., Hirata F. Temperature dependence of the stability of a hydratedelectron: an integral equation study // J. Phys. Chem. – 1994. – V. 98. – N. 38. – P. 96499656.17293. Schnitker J., Rossky P.J., Kenney-Wallace G.A. Electron localization in liquidwater: A computer simulation study of microscopic trapping sites // J. Chem. Phys. – 1986.– V. 85. –N. 5. – P. 2986-2998.94. Nicolas C., Boutin A., Levy B., Borgis D. Molecular simulation of a hydratedelectron at different thermodynamic state points // J.