Why is the atmosphere over land becoming drier? Exploring the roles of atmospheric and land-surface processes on relative humidity

Relative humidity (RH) over land has declined steeply since 2000. This drying is broadly consistent from the edge of the deep tropics to the mid-latitudes of both hemispheres, whereas regions equatorward and poleward show increasing RH trends. The drying trend observed in the gridded global humidity...

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Main Author: Weber, Kirsten Maria Florentine
Format: Thesis
Language:English
Published: 2022
Subjects:
Canada
Greenland
Online Access:https://etheses.whiterose.ac.uk/31123/
https://etheses.whiterose.ac.uk/31123/1/WEBER%20Kirsten%20Maria%20Florentine_Why%20is%20the%20atmosphere%20over%20land%20becoming%20drier.pdf
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record_format openpolar
spelling ftwhiterose:oai:etheses.whiterose.ac.uk:31123 2023-05-15T16:28:42+02:00 Why is the atmosphere over land becoming drier? Exploring the roles of atmospheric and land-surface processes on relative humidity Weber, Kirsten Maria Florentine 2022-03 text https://etheses.whiterose.ac.uk/31123/ https://etheses.whiterose.ac.uk/31123/1/WEBER%20Kirsten%20Maria%20Florentine_Why%20is%20the%20atmosphere%20over%20land%20becoming%20drier.pdf en eng https://etheses.whiterose.ac.uk/31123/1/WEBER%20Kirsten%20Maria%20Florentine_Why%20is%20the%20atmosphere%20over%20land%20becoming%20drier.pdf Weber, Kirsten Maria Florentine orcid:0000-0002-1336-0342 (2022) Why is the atmosphere over land becoming drier? Exploring the roles of atmospheric and land-surface processes on relative humidity. PhD thesis, University of Sheffield. cc_by_nc_nd_4 CC-BY-NC-ND Thesis NonPeerReviewed 2022 ftwhiterose 2023-01-30T21:29:49Z Relative humidity (RH) over land has declined steeply since 2000. This drying is broadly consistent from the edge of the deep tropics to the mid-latitudes of both hemispheres, whereas regions equatorward and poleward show increasing RH trends. The drying trend observed in the gridded global humidity dataset, HadISDH, is not captured by the CMIP5 climate models. This can be mostly explained through thermodynamic drivers, i.e. faster land-than-ocean warming under global warming. Insufficient water vapour is thus evaporated and transported from the oceans to keep RH over land constant. However, there are notable regional and seasonal differences in the trend. This thesis explores how dynamical and terrestrial drivers, which are less well represented in the models, can explain changes in RH. RH was analysed regionally. Strong drying trends were found over eastern Brazil, Tibet, the Caspian Sea, California, Mongolia, southern Africa, southwestern Greenland, eastern USA and the Red Sea. Strong wetting trends were found over Scandinavia, northwestern India and eastern Canada. The relationship between these regional trends and a range of dynamical drivers (precipitation, sea surface temperatures [SST], wind direction and speed, as well as pressure systems and the most common modes of climate variability) were explored. The influence of terrestrial drivers was also examined through evaporation and soil moisture, terrestrial water storage, the vegetation structure, and the modelled carbon cycle response to increased CO2 through CMIP5 experiments. Key findings are as follows. The thermodynamic driver can be detected on small scales (e.g. the Caspian Sea). Of the dynamical drivers, a latitudinal shift of the Intertropical Convergence Zone due to tropical Atlantic SST changes reduced precipitation and thus water availability for RH over eastern Brazil. A wind direction change on different spatial scales leads to changes in RH in many regions (e.g. Greenland, southern Africa, eastern Canada). This work found a complex ... Thesis Greenland White Rose eTheses Online (Universities Leeds, Sheffield, York) Canada Greenland
institution Open Polar
collection White Rose eTheses Online (Universities Leeds, Sheffield, York)
op_collection_id ftwhiterose
language English
description Relative humidity (RH) over land has declined steeply since 2000. This drying is broadly consistent from the edge of the deep tropics to the mid-latitudes of both hemispheres, whereas regions equatorward and poleward show increasing RH trends. The drying trend observed in the gridded global humidity dataset, HadISDH, is not captured by the CMIP5 climate models. This can be mostly explained through thermodynamic drivers, i.e. faster land-than-ocean warming under global warming. Insufficient water vapour is thus evaporated and transported from the oceans to keep RH over land constant. However, there are notable regional and seasonal differences in the trend. This thesis explores how dynamical and terrestrial drivers, which are less well represented in the models, can explain changes in RH. RH was analysed regionally. Strong drying trends were found over eastern Brazil, Tibet, the Caspian Sea, California, Mongolia, southern Africa, southwestern Greenland, eastern USA and the Red Sea. Strong wetting trends were found over Scandinavia, northwestern India and eastern Canada. The relationship between these regional trends and a range of dynamical drivers (precipitation, sea surface temperatures [SST], wind direction and speed, as well as pressure systems and the most common modes of climate variability) were explored. The influence of terrestrial drivers was also examined through evaporation and soil moisture, terrestrial water storage, the vegetation structure, and the modelled carbon cycle response to increased CO2 through CMIP5 experiments. Key findings are as follows. The thermodynamic driver can be detected on small scales (e.g. the Caspian Sea). Of the dynamical drivers, a latitudinal shift of the Intertropical Convergence Zone due to tropical Atlantic SST changes reduced precipitation and thus water availability for RH over eastern Brazil. A wind direction change on different spatial scales leads to changes in RH in many regions (e.g. Greenland, southern Africa, eastern Canada). This work found a complex ...
format Thesis
author Weber, Kirsten Maria Florentine
spellingShingle Weber, Kirsten Maria Florentine
Why is the atmosphere over land becoming drier? Exploring the roles of atmospheric and land-surface processes on relative humidity
author_facet Weber, Kirsten Maria Florentine
author_sort Weber, Kirsten Maria Florentine
title Why is the atmosphere over land becoming drier? Exploring the roles of atmospheric and land-surface processes on relative humidity
title_short Why is the atmosphere over land becoming drier? Exploring the roles of atmospheric and land-surface processes on relative humidity
title_full Why is the atmosphere over land becoming drier? Exploring the roles of atmospheric and land-surface processes on relative humidity
title_fullStr Why is the atmosphere over land becoming drier? Exploring the roles of atmospheric and land-surface processes on relative humidity
title_full_unstemmed Why is the atmosphere over land becoming drier? Exploring the roles of atmospheric and land-surface processes on relative humidity
title_sort why is the atmosphere over land becoming drier? exploring the roles of atmospheric and land-surface processes on relative humidity
publishDate 2022
url https://etheses.whiterose.ac.uk/31123/
https://etheses.whiterose.ac.uk/31123/1/WEBER%20Kirsten%20Maria%20Florentine_Why%20is%20the%20atmosphere%20over%20land%20becoming%20drier.pdf
geographic Canada
Greenland
geographic_facet Canada
Greenland
genre Greenland
genre_facet Greenland
op_relation https://etheses.whiterose.ac.uk/31123/1/WEBER%20Kirsten%20Maria%20Florentine_Why%20is%20the%20atmosphere%20over%20land%20becoming%20drier.pdf
Weber, Kirsten Maria Florentine orcid:0000-0002-1336-0342 (2022) Why is the atmosphere over land becoming drier? Exploring the roles of atmospheric and land-surface processes on relative humidity. PhD thesis, University of Sheffield.
op_rights cc_by_nc_nd_4
op_rightsnorm CC-BY-NC-ND
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