RAINFALL AND EXTRATROPICAL TRANSITION OF TROPICAL CYCLONES: SIMULATION, PREDICTION, AND PROJECTION
Rainfall and associated flood hazards are one of the major threats of tropical cyclones (TCs) to coastal and inland regions. The interaction of TCs with extratropical systems can lead to enhanced precipitation over enlarged areas through extratropical transition (ET). To achieve a comprehensive unde...
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| Other Authors: | , |
| Format: | Other/Unknown Material |
| Language: | English |
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Princeton, NJ : Princeton University
2017
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| Online Access: | http://arks.princeton.edu/ark:/88435/dsp01qr46r348j |
| _version_ | 1821648686908702720 |
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| author | Liu, Maofeng |
| author2 | Smith, James A Civil and Environmental Engineering Department |
| author_facet | Liu, Maofeng |
| author_sort | Liu, Maofeng |
| collection | DataSpace at Princeton University |
| description | Rainfall and associated flood hazards are one of the major threats of tropical cyclones (TCs) to coastal and inland regions. The interaction of TCs with extratropical systems can lead to enhanced precipitation over enlarged areas through extratropical transition (ET). To achieve a comprehensive understanding of rainfall and ET associated with TCs, this thesis conducts weather-scale analyses by focusing on individual storms and climate-scale analyses by focusing on seasonal predictability and changing properties of climatology under global warming. The temporal and spatial rainfall evolution of individual storms, including Hurricane Irene (2011), Hurricane Hanna (2008), and Hurricane Sandy (2012), is explored using the Weather Research and Forecast (WRF) model and a variety of hydrometeorological datasets. ET and Orographic mechanism are two key players in the rainfall distribution of Irene over regions experiencing most severe flooding. The change of TC rainfall under global warming is explored with the Forecast-oriented Low Ocean Resolution (FLOR) climate model under representative concentration pathway (RCP) 4.5 scenario. Despite decreased TC frequency, FLOR projects increased landfalling TC rainfall over most regions of eastern United States, highlighting the risk of increased flood hazards. Increased storm rain rate is an important player of increased landfalling TC rainfall. A higher atmospheric resolution version of FLOR (HiFLOR) model projects increased TC rainfall at global scales. The increase of TC intensity and environmental water vapor content scaled by the Clausius-Clapeyron relation are two key factors that explain the projected increase of TC rainfall. Analyses on the simulation, prediction, and projection of the ET activity with FLOR are conducted in the North Atlantic. FLOR model exhibits good skills in simulating many aspects of present-day ET climatology. The 21st-century-projection under RCP4.5 scenario demonstrates the dominant role of ET events on the projected increase of TC frequency in the eastern North Atlantic, highlighting increased exposure of the northeastern United States and Western Europe to storm hazards. Retrospective seasonal forecast experiments demonstrate the skill of HiFLOR in predicting basinwide and regional ET frequency. This skill, however, is not seen in the seasonal prediction of ET rate. More work on the property of signal-to-noise ratio of ET rate is needed. |
| format | Other/Unknown Material |
| genre | North Atlantic |
| genre_facet | North Atlantic |
| id | ftprincetonuniv:oai:dataspace.princeton.edu:88435/dsp01qr46r348j |
| institution | Open Polar |
| language | English |
| op_collection_id | ftprincetonuniv |
| op_relation | The Mudd Manuscript Library retains one bound copy of each dissertation. Search for these copies in the library's main catalog: catalog.princeton.edu http://arks.princeton.edu/ark:/88435/dsp01qr46r348j |
| publishDate | 2017 |
| publisher | Princeton, NJ : Princeton University |
| record_format | openpolar |
| spelling | ftprincetonuniv:oai:dataspace.princeton.edu:88435/dsp01qr46r348j 2025-01-16T23:39:59+00:00 RAINFALL AND EXTRATROPICAL TRANSITION OF TROPICAL CYCLONES: SIMULATION, PREDICTION, AND PROJECTION Liu, Maofeng Smith, James A Civil and Environmental Engineering Department 2017 http://arks.princeton.edu/ark:/88435/dsp01qr46r348j en eng Princeton, NJ : Princeton University The Mudd Manuscript Library retains one bound copy of each dissertation. Search for these copies in the library's main catalog: catalog.princeton.edu http://arks.princeton.edu/ark:/88435/dsp01qr46r348j Extratropical Transition Global Warming Rainfall Tropical Cyclone Environmental engineering Atmospheric sciences Academic dissertations (Ph.D.) 2017 ftprincetonuniv 2022-04-10T21:00:06Z Rainfall and associated flood hazards are one of the major threats of tropical cyclones (TCs) to coastal and inland regions. The interaction of TCs with extratropical systems can lead to enhanced precipitation over enlarged areas through extratropical transition (ET). To achieve a comprehensive understanding of rainfall and ET associated with TCs, this thesis conducts weather-scale analyses by focusing on individual storms and climate-scale analyses by focusing on seasonal predictability and changing properties of climatology under global warming. The temporal and spatial rainfall evolution of individual storms, including Hurricane Irene (2011), Hurricane Hanna (2008), and Hurricane Sandy (2012), is explored using the Weather Research and Forecast (WRF) model and a variety of hydrometeorological datasets. ET and Orographic mechanism are two key players in the rainfall distribution of Irene over regions experiencing most severe flooding. The change of TC rainfall under global warming is explored with the Forecast-oriented Low Ocean Resolution (FLOR) climate model under representative concentration pathway (RCP) 4.5 scenario. Despite decreased TC frequency, FLOR projects increased landfalling TC rainfall over most regions of eastern United States, highlighting the risk of increased flood hazards. Increased storm rain rate is an important player of increased landfalling TC rainfall. A higher atmospheric resolution version of FLOR (HiFLOR) model projects increased TC rainfall at global scales. The increase of TC intensity and environmental water vapor content scaled by the Clausius-Clapeyron relation are two key factors that explain the projected increase of TC rainfall. Analyses on the simulation, prediction, and projection of the ET activity with FLOR are conducted in the North Atlantic. FLOR model exhibits good skills in simulating many aspects of present-day ET climatology. The 21st-century-projection under RCP4.5 scenario demonstrates the dominant role of ET events on the projected increase of TC frequency in the eastern North Atlantic, highlighting increased exposure of the northeastern United States and Western Europe to storm hazards. Retrospective seasonal forecast experiments demonstrate the skill of HiFLOR in predicting basinwide and regional ET frequency. This skill, however, is not seen in the seasonal prediction of ET rate. More work on the property of signal-to-noise ratio of ET rate is needed. Other/Unknown Material North Atlantic DataSpace at Princeton University |
| spellingShingle | Extratropical Transition Global Warming Rainfall Tropical Cyclone Environmental engineering Atmospheric sciences Liu, Maofeng RAINFALL AND EXTRATROPICAL TRANSITION OF TROPICAL CYCLONES: SIMULATION, PREDICTION, AND PROJECTION |
| title | RAINFALL AND EXTRATROPICAL TRANSITION OF TROPICAL CYCLONES: SIMULATION, PREDICTION, AND PROJECTION |
| title_full | RAINFALL AND EXTRATROPICAL TRANSITION OF TROPICAL CYCLONES: SIMULATION, PREDICTION, AND PROJECTION |
| title_fullStr | RAINFALL AND EXTRATROPICAL TRANSITION OF TROPICAL CYCLONES: SIMULATION, PREDICTION, AND PROJECTION |
| title_full_unstemmed | RAINFALL AND EXTRATROPICAL TRANSITION OF TROPICAL CYCLONES: SIMULATION, PREDICTION, AND PROJECTION |
| title_short | RAINFALL AND EXTRATROPICAL TRANSITION OF TROPICAL CYCLONES: SIMULATION, PREDICTION, AND PROJECTION |
| title_sort | rainfall and extratropical transition of tropical cyclones: simulation, prediction, and projection |
| topic | Extratropical Transition Global Warming Rainfall Tropical Cyclone Environmental engineering Atmospheric sciences |
| topic_facet | Extratropical Transition Global Warming Rainfall Tropical Cyclone Environmental engineering Atmospheric sciences |
| url | http://arks.princeton.edu/ark:/88435/dsp01qr46r348j |