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dc.contributor.authorKong, Xiangrui
dc.date.accessioned2014-05-12T11:31:13Z
dc.date.available2014-05-12T11:31:13Z
dc.date.issued2014-05-12
dc.identifier.isbn978-91-628-9024-7
dc.identifier.urihttp://hdl.handle.net/2077/35126
dc.description.abstractClouds and aerosols play important roles in the climate system by affecting on atmospheric chemistry, the radiation budget of the atmosphere, and the water cycle including the formation of precipitation. Climate models with predictive power require quantitative descriptions of aerosols and clouds, but several key processes remain to be fully understood. One important example is the formation and growth of ice particles in clouds. Organic compounds also form secondary organic aerosol and coatings on existing particles including ice nuclei and ice cloud particles, which further complicate the description of cloud processes. To improve the understanding of these processes, some fundamental investigations of atmospherically relevant interface interactions are carried out, and the results and findings are summarized and discussed in this thesis. The investigations use a newly developed environmental molecular beam (EMB) technique as the main experimental method. The principle, design and demonstration of the EMB method are described in detail. The method allows for ice surface investigations at temperatures up to 213 K, and it is employed to study gas-surface interactions under conditions relevant to the troposphere. The main findings of this thesis are related to three research themes: (1) Ice formation via deposition mode nucleation on hydrophobic and hydrophilic surfaces is characterized. The critical supersaturation required to activate nucleation on various surfaces increases rapidly with decreasing temperature below 200 K, and adsorbed organic compounds are observed to influence the nucleation, structure and growth rate of ice. (2) Water uptake by bare ice and coated ice surfaces is investigated. The accommodation and desorption kinetics for water on bare ice is quantitatively described by a precursor model. Coatings on ice have a significant impact on water uptake, and adsorption of acids commonly found in the atmosphere tends to enhance water accommodation. (3) Water interactions with surfaces on condensed organic phases and organic coatings on graphite are characterized. Bulk accommodation is inefficient on solid organic surfaces, while water uptake is efficient on liquid phases. The surface layer on condensed n-butanol is shown to change gradually from solid to liquid over a 10 K temperature span around the bulk melting temperature, with major implications for water uptake. The thesis includes the development of new experimental methods and an improved molecular-level understanding of processes at gas-solid and gas-liquid interfaces, and thereby contributes to a better description of cloud and aerosol processes in the environment.sv
dc.language.isoengsv
dc.relation.haspartEnvironmental molecular beam studies of ice surface processes. Xiangrui Kong, Patrik U. Andersson, Nikola Markovic, and Jan B.C. Pettersson. Proceedings of the 12th International Conference on the Physics and Chemistry of Ice, Hokkaido University Press, Sapporo, 2011, 79-88.sv
dc.relation.haspartIce Formation via Deposition Mode Nucleation on Bare and Alcohol Covered Graphite Surfaces. Xiangrui Kong, Patrik U. Andersson, Erik S. Thomson, and Jan B. C. Pettersson. Journal of Physical Chemistry C, 2012, 116 (16), 8964–8974. ::doi::10.1021/jp212235psv
dc.relation.haspartDeposition mode ice nucleation reexamined at temperatures below 200 K. Erik S. Thomson, Xiangrui Kong, Panos Papagiannakopoulos, Nikola Markovic, and Jan B.C. Pettersson. Manuscript for Atmospheric Chemistry and Physics.sv
dc.relation.haspartWater Accommodation and Desorption Kinetics on Ice. Xiangrui Kong, Panos Papagiannakopoulos, Erik S. Thomson, Nikola Markovic, and Jan B.C. Pettersson. Submitted to Journal of Physical Chemistry A.sv
dc.relation.haspartCollision Dynamics and Solvation of Water Molecules in a Liquid Methanol Film. Erik S. Thomson, Xiangrui Kong, Patrik U. Andersson, Nikola Markovic, and Jan B. C. Pettersson. Journal of Physical Chemistry Letters, 2011, 2 (17), 2174–2178. ::doi::10.1021/jz200929ysv
dc.relation.haspartWater Interactions with Acetic Acid Layers on Ice and Graphite. Panos Papagiannakopoulos, Xiangrui Kong, Erik S. Thomson, and Jan B.C. Pettersson. Submitted to Journal of Physical Chemistry B.sv
dc.relation.haspartSurface Transformations and Water Uptake on Liquid and Solid Butanol near the Melting Temperature. Panos Papagiannakopoulos, Xiangrui Kong, Erik S. Thomson, Nikola Markovic, and Jan B.C. Pettersson. Journal of Physical Chemistry C, 117 (2013) 6678-6685. ::doi::10.1021/jp4003627sv
dc.relation.haspartCollision Dynamics and Uptake of Water on Alcohol-covered Ice. Erik S. Thomson, Xiangrui Kong, Nikola Markovic, Panos Papagiannakopoulos, and Jan B.C. Pettersson. Atmospheric Chemistry and Physics, 13 (2013) 2223-2233. ::doi::10.5194/acp-13-2223-2013sv
dc.relation.haspartWater Accommodation on Ice and Organic Surfaces: Insights from Environmental Molecular Beam Experiments. Xiangrui Kong, Erik S. Thomson, Panos Papagiannakopoulos, Sofia Johansson, and Jan B.C. Pettersson. Submitted to Journal of Physical Chemistry B.sv
dc.subjectatmospheresv
dc.subjectkineticssv
dc.subjectEnvironmental molecular beamsv
dc.subjectice nucleationsv
dc.subjectsupersaturationsv
dc.subjectaccommodation coefficientsv
dc.subjectphase transitionsv
dc.subjectalcoholssv
dc.subjectgreen chemistrysv
dc.titleMolecular investigations of atmospherically relevant interface processes: ice formation and water accommodation on ice and organic surfacessv
dc.typeTextswe
dc.type.svepDoctoral thesiseng
dc.gup.mailkongx@chem.gu.sesv
dc.type.degreeDoctor of Philosophysv
dc.gup.originUniversity of Gothenburg. Faculty of Sciencesv
dc.gup.departmentDepartment of Chemistry and Molecular Biology ; Institutionen för kemi och molekylärbiologisv
dc.gup.defenceplace13:15 in lecture hall KB at Kemigården 4sv
dc.gup.defencedate2014-06-02
dc.gup.dissdb-fakultetMNF


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