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Title

Statistical precipitation downscaling for small-scale hydrological impact investigations of climate change

Publication Year

2011

Author(s)
  • Willems, P.
  • Vrac, M.
Source
JOURNAL OF HYDROLOGY Volume: 402 Issue: 3-4 Pages: 193-205 Published: 2011
ISSN
0022-1694
Abstract

Impact investigations of climate change on urban drainage require projections to be made on short-duration precipitation extremes. The relevant time scales can be as low as 10 min, which requires strong statistical downscaling of climate model simulation results. In this research, two sets of methods have been suggested and tested based on Belgian data. The first set makes direct use of the precipitation results of the climate models. They involve computation of quantile perturbations on extreme precipitation intensities, and the tested assumption that the same perturbations hold for daily and sub-daily time scales. The second set of methods is based on weather typing, and accounts for the low accuracy of daily precipitation results in current climate modelling. In these methods, climate model outputs on pressure (atmospheric circulation) are used to obtain precipitation estimates from analogue days in the past. Different criteria for defining analogue days have been tested. The weather typing methods have been further advanced accounting for the fact that precipitation change does not only depend on change in atmospheric circulation, but also on temperature rise. Results have been investigated as changes to precipitation intensity-duration-frequency (IDF) relationships. It is shown that both the quantile-perturbation and advanced weather typing based methods allow precipitation biases in climate model simulation results to be largely corrected. Both types of methods moreover produce similar short-duration changes in precipitation extremes, which gives some credibility to the downscaled impacts. The corresponding changes in IDE statistics show that the extreme precipitation quantiles typically used for design of urban drainage systems, can increase up to 30% by the end of this century. Those changes mean that sewer surcharge or flooding would occur about twice more frequently than in the present climate (if no other environmental or management changes are accounted for). This would have a significant impact on future urban water management and planning. (C) 2011 Elsevier B.V. All rights reserved.

Author Keyword(s)
  • Climate change
  • Precipitation
  • Statistical downscaling
  • Urban drainage
  • Weather typing
KeyWord(s) Plus
  • TEMPERATURE
  • SCENARIOS
ESI Discipline(s)
  • Engineering
  • Environment/Ecology
  • Geosciences
Web of Science Category(ies)
  • Engineering, Civil
  • Geosciences, Multidisciplinary
  • Water Resources
Adress(es)

[Willems, P.] Katholieke Univ Leuven, Dept Civil Engn, Hydraul Div, BE-3001 Louvain, Belgium; [Willems, P.] Vrije Univ Brussel, Dept Hydrol & Hydraul Engn, BE-1050 Brussels, Belgium; [Vrac, M.] CE Saclay Orme Merisiers, UVSQ, CNRS, Lab Sci Climat & Environm,CEA,UMR 1572, F-91191 Gif Sur Yvette, France

Reprint Adress

Willems, P (reprint author), Katholieke Univ Leuven, Dept Civil Engn, Hydraul Div, Kasteelpk Arenberg 40, BE-3001 Louvain, Belgium.

Country(ies)
  • Belgium
  • France
CNRS - Adress(es)
  • Laboratoire des sciences du climat et de l'environnement (LSCE), UMR8212
Accession Number
WOS:000291192900003
uid:/L1S05SRT
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