Диссертация (Химически модифицированные нанокомпозиты на основе серебра для спектроскопии гигантского комбинационного рассеяния маркеров нефтепродуктов), страница 35
Описание файла
Файл "Диссертация" внутри архива находится в папке "Химически модифицированные нанокомпозиты на основе серебра для спектроскопии гигантского комбинационного рассеяния маркеров нефтепродуктов". PDF-файл из архива "Химически модифицированные нанокомпозиты на основе серебра для спектроскопии гигантского комбинационного рассеяния маркеров нефтепродуктов", 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 35 страницы из PDF
2012. Vol. 5. P. 4233 – 4250.251.Mitrevski B., Amer M.W. et al. Evaluation of comprehensive two-dimensional gaschromatography with flame photometric detection: Potential application for sulfurspeciation in shale oil // Anal. Chim. Acta. 2013. Vol. 803. P. 174 – 180.252.Kropp K.G., Fedorak P.M. A review of the occurrence, toxicity, and biodegradationof condensed thiophenes found in petroleum // Can. J.
Microbiol. 1998. Vol. 44. P.605 – 622.253.Campos-Martin J.M., Capel-Sanchez M.C. et al. Oxidative processes ofdesulfurization of liquid fuels // J. Chem. Technol. Biotechnol. 2010. Vol. 85. P.879 – 890.254.Babich I.V., Moulijin J.A. Science and technology of novel processes for deepdesulfurization of oil refinery streams: a review // Fuel.
2003. Vol. 82. P. 607 – 631.200255.Li F., Liu R. et al. Desulfurization of dibenzothiophene by chemical oxidation andsolvent extraction with Me3NCH2C6H5Cl·2ZnCl2 ionic liquid // Green Chem. 2008.Vol. 11. P. 883 – 888.256.Seixas de Melo J., Pina J. et al. A comprehensive study of the spectral andphotophysical properties of arylthiophenes // J. Photochem. Photobiol.
A. 2008.Vol. 194. P. 67 – 75.257.Новиков Е.А. Определение серы в нефтепродуктах. Обзор аналитическихметодов // Мир нефтепродуктов. Вестник нефтяных компаний. 2008. № 1 – 5.С. 1 – 39.258.Xu J., Du J. et al. Facile Detection of Polycyclic Aromatic Hydrocarbons by aSurface-Enhanced Raman Scattering Sensor Based on the Au Coffee Ring Effect //ACS Appl. Mater. Interfaces. 2014.
Vol. 6. P. 6891 − 6897.259.Chen J., Huang Y. and Zhao Y. Characterization of polycyclic aromatichydrocarbons using Raman and surface-enhanced Raman spectroscopy // J. RamanSpectrosc. 2015. Vol. 46. P. 64 – 69.260.Leyton P., Sanchez-Cortez S. et al. Selective Molecular Recognition of PolycyclicAromatic Hydrocarbons (PAHs) on Calix[4]arene-Functionalized Ag Nanoparticlesby Surface-Enhanced Raman Scattering // J. Phys. Chem. B. 2004.
Vol. 108. P.17484 – 17490.261.Morf P., Raimondi F. et al. Dithiocarbamates: Functional and Versatile Linkers forthe Formation of Self-Assembled Monolayers // Langmuir. 2006. Vol. 22. P. 658 –663.262.Guerrini L., Garsia-Ramos J. et al. Self-assembly of a dithiocarbamate calix[4]arene on Ag nanoparticles and its application in the fabrication of surfaceenhanced Raman scattering based nanosensors // Phys. Chem. Phys. 2009. Vol. 11.P. 1787 – 1793.263.Guerrini L., Garsia-Ramos J., Sanchez-Cortes S. Sensing polycyclic aromatichydrocarbons with dithiocarbamate-functionalized Ag nanoparticles by surfaceenhanced Raman scattering // Anal.
Chem. 2009. Vol. 81. P. 1418 – 1425.264.Xie Y., Wang X. et al. Selective SERS detection of each polycyclic aromatichydrocarbon (PAH) in a mixture of five kinds of PAHs // J. Raman Spectrosc. 2011.Vol. 42. P. 945 – 950.201265.Leyton P., Córdova I. et al. Humic acids as molecular assemblers in the surfaceenhanced Raman scattering detection of polycyclic aromatic hydrocarbons // Vibrat.Spectrosc. 2008. Vol. 46, № 2. P.
77 – 81.266.Giger W., Blumer M. Polycyclic aromatic hydrocarbons in the environment.Isolation and characterization by chromatography, visible, ultraviolet, and massspectrometry // Anal. Chem. 1974. Vol. 46, № 12. P. 1663 – 1671.267.Vo-Dinh T., Hiromoto M.Y. K. et al. Surface-enhanced Raman spectrometry fortrace organic analysis // Anal. Chem.
1984. Vol. 56, № 9. P. 1667 – 1670.268.Enlow P.D., Vo-Dinh T. Detection of nitro-polynuclear aromatic compounds bysurface-enhanced Raman spectrometry // Anal. Chem. 1986. Vol. 58, № 6. P. 1119– 1123.269.Stewart D. and Fredericks P. Fourier transform surface-enhanced Raman scatteringfor the detection and identification of polyaromatic hydrocarbons // J. RamanSpectr. 1995. Vol.
26. P. 629 – 635.270.Liu X., Cao L. et al. Functionalizing Metal Nanostructured Film with GrapheneOxide for Ultrasensitive Detection of Aromatic Molecules by Surface-EnhancedRaman Spectroscopy // ACS Appl. Mater. Interfaces. 2011. Vol. 3.
P. 2944 – 2952.271.Караханов Э.А., Максимов А.Л. и Рунова Е.А. Создание супрамолекулярныхметаллокомплексныхкаталитическихсистемдляорганическогоинефтехимического синтеза // Усп. хим. 2005. Т. 74, № 1. С. 104 – 119.272.Socrates G. Infrared and Raman characteristic group frequencies: tables and charts// Chichester: John Wiley & Sons Ltd. 2001. P. 347.273.Khin M.M., Nair A.S. et al. A review on nanomaterials for environmentalremediation // Energy Environ.
Sci. 2012. Vol. 5. P. 8075 – 8109.274.Kubackova J., Fabriciova G. et al. Sensitive Surface-Enhanced RamanSpectroscopy (SERS) Detection of Organochlorine Pesticides by Alkyl DithiolFunctionalized Metal Nanoparticles-Induced Plasmonic Hot Spots // Anal. Chem.2015. Vol.
87, № 1. P. 663 – 669.275.Foo K.Y., Hameed B.H. Insights into the modeling of adsorption isotherm systems// Chemical Engineering Journal. 2010. Vol. 156. P. 2 – 10.276.Ko H. and Tsukruk V.V. Nanoparticle-Decorated Nanocanals for Surface-EnhancedRaman Scattering // Small. 2008. Vol. 4, № 11. P. 1980 – 1984.202277.Moore D.S. Instrumentation for trace detection of high explosives // Rev. Sci.Instrum. 2004.
Vol. 75. P. 2499.278.Lau K.H.A., Tan L.-S. et al. Highly Sensitive Detection of Processes OccurringInside Nanoporous Anodic Alumina Templates: A Waveguide Optical Study // J.Phys. Chem. B. 2004. Vol. 108, № 30. P. 10812 – 10818.279.Thery-Merland F., Methivier C. et al. Adsorption of functionalised thiols on goldsurfaces: How to build a sensitive and selective sensor for a nitroaromaticcompound // Sens.
Actuators, B. 2006. Vol. 114. P. 223 – 228.280.Ensafi A., Fouladgar M. Development of a mercury optical sensor based onimmobilization of 4-(2-pyridylazo)-resorcinol on a triacetylcellulose membrane //Sens. Actuators, B. 2006. Vol. 113. P. 88 – 93.281.Alvarez-Puebla R.A., Liz-Marzán L.M. SERS detection of small inorganicmolecules and ions // Angew Chem Int. 2012. Vol. 51, № 49. P. 11214 – 11223.282.Wang G., Lim C. et al. Surface-enhanced Raman scattering in nanoliter droplets:towards high-sensitivity detection of mercury (II) ions // Anal Bioanal Chem.
2009.Vol. 394. P. 1827 – 1832.283.Li K., Liang A. et al. A stable and reproducible nanosilver-aggregation-4mercaptopyridine surface-enhanced Raman scattering probe for rapid determinationof trace Hg2+ // Talanta. 2012. Vol. 99. P. 890 – 896.284.Chen Y., Wu L. et al. Determination of mercury (II) by surface-enhanced Ramanscattering spectroscopy based on thiol-functionalized silver nanoparticles //Microchim Acta.
2012. Vol. 177. P. 341 – 348.285.Li P., Liu H. et al. Sensitive and selective SERS probe for Hg (II) detection usingaminated ring-close structure of Rhodamine 6G // Talanta. 2013. Vol. 106. P. 381 –387.286.Ma Y., Liu H. et al. A displacement principle for mercury detection by opticalwaveguide and surface enhanced Raman spectroscopy // J. Colloid Interface Sci.2012.
Vol. 386. P. 451 – 455.287.Wang Y., Irudayaraj J. A SERS DNAzyme biosensor for lead ion detection // Chem.Commun. 2011. Vol. 47. P. 4394 – 4396.203288.Sarkar S., Pradhan M. et al. Selective and Sensitive Recognition of Cu2+ in anAqueous Medium: A Surface-Enhanced Raman Scattering (SERS)-Based Analysiswith a Low-Cost Raman Reporter // Chem. Eur. J.
2012. Vol. 18. P. 6335 – 6342.289.Ye Y., Liu H. et al. Sensitive and selective SERS probe for trivalent chromiumdetection using citrate attached gold nanoparticles // Nanoscale. 2012. Vol. 4. P.6442 – 6448.290.Yin J., Wu T. et al. SERS-Active Nanoparticles for Sensitive and SelectiveDetection of Cadmium Ion (Cd2+) // Chem.
Mater. 2011. Vol. 23, № 21. P. 4756 –4764.291.Mohana D., Pittman Jr. Arsenic removal from water/wastewater using adsorbents –A critical review // J. Hazard. Mater. 2007. Vol. 142. P. 1 – 53.292.Mulvihill M., Tao A. et al. Surface-enhanced Raman spectroscopy for trace arsenicdetection in contaminated water // Angew Chem. 2008. Vol.
120. P. 6556 – 6560.293.Xu Z., Hao J. et al. Surface enhanced Raman spectroscopy of arsenate and arseniteusing Ag nanofilm prepared by modified mirror reaction // J Colloid Interf Sci.2010. Vol. 347. P. 90 – 95.294.Han M., Hao J. et al. Surface-enhanced Raman scattering for arsenate detection onmultilayer silver nanofilms // Anal. Chim. Acta. 2011. Vol. 692. P. 96 – 102.295.Du J., Cui J. and Jing C. Rapid in situ identification of arsenic species using aportable Fe3O4@Ag SERS sensor // Chem. Commun.
2014. Vol. 50. P. 347 – 349.296.Bao L., Mahurin S.M. et al. Silver-Doped Sol−Gel Film as a Surface-EnhancedRaman Scattering Substrate for Detection of Uranyl and Neptunyl Ions // Anal.Chem. 2003. Vol. 75, № 23. P. 6614 – 6620.297.Burneau A., Teiten B. Surface-enhanced raman spectra of both uranyl (VI) and 2(5-bromo-2-pyridylazo)-5-diethylaminophenol in silver colloids // Vib. Spectrosc.1999. Vol.
