Climate change and uncertainty in high-resolution rainfall extremes

Kianfar, Bahareh; Fatichi, Simone; Paschalis, Alec; Maurer, Max; Molnár, Péter

doi:10.5194/hess-2016-536

“…Since rainfall and hydrologic performance are linked, changes in rainfall caused by climate change are also expected to alter the ability of green infrastructure to reduce combined sewer overflows, mitigate urban runoff, or comply with stormwater management regulations. Findings from prior research, primarily focused on changes in GSI discharge quality, are consistent with other climate impacts studies that illustrate that future impacts are deeply uncertain and depend on the climate change scenario used in modeling (Cook et al, 2017;Hall, 2014;Kianfar et al, 2016;Musau et al,). Zhang et al (2019) evaluated the pollution treatment performance of constructed wetlands and found notable differences in performance when different climate models were used.…”

Section: Introductionsupporting

confidence: 75%

Using rainfall measures to evaluate hydrologic performance of green infrastructure systems under climate change

Cook

¹

,

VanBriesen

²

,

Samaras

³

2019

Sustainable and Resilient Infrastructure

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“…At plot scale,Xia et al (2013) showed that, for cropland in China, I 10 , I 20 , I 30 , or I 60 were significantly correlated with event losses of N and P and offered some hypotheses about why one or another index of intensity should become significant at a particular field site Nunes et al (2011). also stressed the explanatory power of I 10 and I 60 for erosion under various cover types in Portugal, as didKiassari et al (2012) for erosion plots in semi-arid Iran.…”

mentioning

confidence: 90%

Rainfall intensity bursts and the erosion of soils: an analysis highlighting the need for high temporal resolution rainfall data for research under current and future climates

Dunkerley

¹

2019

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Abstract. Many land surface processes, including splash dislodgment and downslope transport of soil materials, are influenced strongly by short-lived peaks in rainfall intensity but are less well accounted for by longer-term average rates. Specifically, rainfall intensities reached over periods of 10–30 min appear to have more explanatory power than hourly or longer-period data. However, most analyses of rainfall, and particularly scenarios of possible future rainfall extremes under climate change, rely on hourly data. Using two Australian pluviograph records with 1 s resolution, one from an arid and one from a wet tropical climate, the nature of short-lived “intensity bursts” is analysed from the raw inter-tip times of the tipping bucket gauges. Hourly apparent rainfall intensities average just 1.43 mm h−1 at the wet tropical site and 2.12 mm h−1 at the arid site. At the wet tropical site, intensity bursts of extreme intensity occur frequently, those exceeding 30 mm h−1 occurring on average at intervals of <1 d and those of >60 mm h−1 occurring on average at intervals of <2 d. These bursts include falls of 13.2 mm in 4.4 min, the equivalent of 180 mm h−1, and 29 mm in 12.6 min, equivalent to 138 mm h−1. Intensity bursts at the arid site are much less frequent, those of 50–60 mm h−1 occurring at intervals of ∼1 month; moreover, the bursts have a much shorter duration. The aggregation of rainfall data to hourly level conceals the occurrence of many of these short-intensity bursts, which are potentially highly erosive. A short review examines some of the mechanisms through which intensity bursts affect infiltration, overland flow, and soil dislodgment. It is proposed that more attention to resolving these short-lived but important aspects of rainfall climatology is warranted, especially in light of possible changes in rainfall extremes under climate change.

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“…A common approach to the analysis of extreme rainfall intensities is the use of downscaling from daily maxima to sub-daily values, though this is normally only extended to the prediction of hourly maxima. Sub-hourly rainfall data are generated in some canonical cascade downscaling models (Kianfar et al 2016, Haddad & Rahman 2014, Paschalis et al 2014, Pohle et al 2018) though with only moderate success in generating realistic intensities. As noted by Forestieri et al (2018) downscaling can be undertaken by using correlations between daily and sub-daily maxima established from historical data, on the presumption that the correlations will remain invariant under climate change.…”

Section: Short-term Intensity Bursts and Climate Changementioning

confidence: 99%

Rainfall intensity bursts and the erosion of soils: an analysis highlighting the need for high temporal resolution rainfall data for research under current and future climates

Dunkerley¹

2019

Preprint

0

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Abstract. Many landsurface processes, including splash dislodgment and downslope transport of soil materials, are influenced strongly by short-lived peaks in rainfall intensity but are less well accounted for by longer-term average rates. Specifically, rainfall intensities reached over periods of 10–30 minutes appear to have more explanatory power than hourly or longer-period data. However, most analyses of rainfall, and particularly scenarios of possible future rainfall extremes under climate change, rely on hourly data. Using two Australian pluviograph records with 1 second resolution, one from an arid and one from a wet tropical climate, the nature of short-lived intensity bursts is analysed from the raw inter-tip times of the tipping bucket gauges. Hourly apparent rainfall intensities average just 1.43 mm h−1 at the wet tropical site, and 2.12 mm h−1 at the arid site. At the wet tropical site, intensity bursts of extreme intensity occur frequently, those exceeding 30 mm h−1 occurring on average at intervals of 60 mm h−1 occurring on average at intervals of

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Climate change and uncertainty in high-resolution rainfall extremes

Cited by 3 publications

References 61 publications

Using rainfall measures to evaluate hydrologic performance of green infrastructure systems under climate change

Using rainfall measures to evaluate hydrologic performance of green infrastructure systems under climate change

Rainfall intensity bursts and the erosion of soils: an analysis highlighting the need for high temporal resolution rainfall data for research under current and future climates

Rainfall intensity bursts and the erosion of soils: an analysis highlighting the need for high temporal resolution rainfall data for research under current and future climates

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