Observing and Modeling Precipitation in the Tibetan Plateau region - from large-scale processes to convective storms
Abstract
Climate change in mountain regions has far-reaching societal impacts such as increased risks for natural hazards and water scarcity that may affect billions of people in the downstream regions. Precipitation changes play a critical role in these impacts due to their effects on river runoff and flooding. However, these changes remain hard to predict due to uncertainties in
climate models and a lack of reliable observations.
This dissertation aims to enhance the understanding of precipitation and its underlying large-scale and mesoscale processes in the Tibetan Plateau (TP) region, one of the most extensive and vulnerable mountain regions in the world. More specifically, the dissertation combines gauge measurements, satellite observations, reanalysis data, and high-resolution model simulations to investigate present-climate characteristics of clouds and precipitation over TP and its downstream regions.
A key outcome is a data set of large storms, so-called mesoscale convective systems (MCSs), based on two decades of high-resolution satellite observations of clouds and precipitation. This data set is used to study MCS characteristics and their relation to large-scale atmospheric circulation systems and water vapor transport. Satellite observations reveal that MCSs are important precipitation producers in the river basins surrounding the TP, while convection over the TP occurs in a more scattered manner with significantly less precipitation. In addition, satellite observations are used to evaluate kilometer-scale simulations of MCSs. The model simulations capture the general spatial pattern and magnitude of MCS-associated precipitation but show also systematic biases in MCS frequencies in some regions south and east of the TP.
It was found that interactions between large- and mesoscale processes affect the formation
and evolution of MCSs over the TP and its downstream regions. The results identify several
processes, e.g. interactions between the TP and the mid-latitude westerly circulation, that
may drive future precipitation changes and need to be realistically represented in future
climate model projections. As such, this dissertation constitutes a step towards reliable
projections of climate change in the TP region.
Parts of work
Kukulies , J., Chen, D., & Wang, M. (2019). Temporal and spatial variations of convection and precipitation over the Tibetan Plateau based on recent satellite observations. Part I: Cloud climatology derived from CloudSat and CALIPSO. International Journal of Climatology, 39(14), 5396-5412. https://doi.org/10.1002/joc.6162 Kukulies, J., Chen, D., & Wang, M. (2020). Temporal and spatial variations of convection, clouds, and precipitation over the Tibetan Plateau from recent satellite observations. Part II: Precipitation climatology derived from global precipitation measurement mission. International Journal of Climatology. https://doi.org/10.1002/joc.6493 Lai, H. W., Chen, H. W., Kukulies, J., Ou, T., & Chen, D. (2020). Regionalization of
seasonal precipitation over the Tibetan Plateau and associated large-scale atmospheric
systems. Journal of Climate, 1-45. https://doi.org/10.1175/JCLI-D-20-0521.1 Kukulies, J., Chen, D., & Curio, J. (2021). The Role of Mesoscale Convective Systems in Precipitation in the Tibetan Plateau region. Journal of Geophysical Research: Atmospheres, 126(23), e2021JD035279. https://doi.org/10.1029/2021JD035279 Kukulies, J., Prein, A., Curio, J., Chen, D (2022). Kilometer-scale multi-physics multi- model simulations of a mesoscale convective system in the lee of the Tibetan Plateau: Implications for climate simulations Revision submitted to Journal of Climate. Kukulies, J., Li, W., Chen, D (2022). Time scales of summer water vapor transport downwind of the Tibetan Plateau in reanalysis and dynamically downscaled data. Manuscript draft. Kukulies, J., Lai, H., Curio, J., Feng, C., Li, P., Lin, C., Sugimoto, S., Ou, T. and Chen, D. Mesoscale convective systems in the Third Pole region: characteristics, mechanisms and impact on precipitation. Submitted to Frontiers in Earth Science.
Degree
Doctor of Philosophy
University
University of Gothenburg
Institution
Department of Earth Sciences ; Institutionen för geovetenskaper
Disputation
Fredagen den 24 mars 2023, kl. 13.30, Hörsalen, Geovetarcentrum, Guldhedsgatan 5C, Göteborg
Date of defence
2023-03-24
julia.kukulies@gu.se
Date
2023-02-20Author
Kukulies, Julia
Keywords
Tibetan Plateau
Water cycle
Precipitation
Climate modeling
Mesoscale convective systems
Large-scale atmospheric circulation
Publication type
Doctoral thesis
ISBN
978-91-8069-142-0 (PDF)
978-91-8069-141-3 (print)
Language
eng