The hydro‐meteorological estimation of probable maximum precipitation under varying scenarios in Sri Lanka

Fernando, W. C. D. K.; Wickramasuriya, Samiru Sudharaka

doi:10.1002/joc.2096

Cited by 27 publications

(20 citation statements)

References 23 publications

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“…Probable maximum precipitation (PMP) is defined as “ the greatest depth of precipitation for a given duration meteorologically possible for a design watershed or a given storm area at a particular location at a particular time of year ” [ World Meteorological Organization , ], and it represents the largest rainfall that could physically occur under a series of adverse atmospheric conditions [ Casas et al ., , ; Douglas and Barros , ; Schreiner and Riedel , ; Fernando and Wickramasuriya , ]. Distinguished from the statistically based T ‐year extreme rainfall estimate that associates depth with annual exceedance probability (AEP = 1/ T ) [see Kao and Ganguly , ], PMP is the deterministic upper bound of extreme storms.…”

Section: Introductionmentioning

confidence: 99%

Effects of climate change on probable maximum precipitation: A sensitivity study over the Alabama‐Coosa‐Tallapoosa River Basin

et al. 2017

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Probable maximum precipitation (PMP), defined as the largest rainfall depth that could physically occur under a series of adverse atmospheric conditions, has been an important design criterion for critical infrastructures such as dams and nuclear power plants. To understand how PMP may respond to projected future climate forcings, we used a physics‐based numerical weather simulation model to estimate PMP across various durations and areas over the Alabama‐Coosa‐Tallapoosa (ACT) River Basin in the southeastern United States. Six sets of Weather Research and Forecasting (WRF) model experiments driven by both reanalysis and global climate model projections, with a total of 120 storms, were conducted. The depth‐area‐duration relationship was derived for each set of WRF simulations and compared with the conventional PMP estimates. Our results showed that PMP driven by projected future climate forcings is higher than 1981–2010 baseline values by around 20% in the 2021–2050 near‐future and 44% in the 2071–2100 far‐future periods. The additional sensitivity simulations of background air temperature warming also showed an enhancement of PMP, suggesting that atmospheric warming could be one important factor controlling the increase in PMP. In light of the projected increase in precipitation extremes under a warming environment, the reasonableness and role of PMP deserve more in‐depth examination.

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Section: Introductionmentioning

confidence: 99%

Effects of climate change on probable maximum precipitation: A sensitivity study over the Alabama‐Coosa‐Tallapoosa River Basin

et al. 2017

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“…Therefore, this factor is not taken into consideration, which reduces the methodology to equation (4), where the maximization is determined only by the moisture factor, as explained in Section 2.5.2. As a consequence of this assumption, lower PMP estimations are obtained, as Fernando and Wickramasuriya (2010) concluded.…”

Section: Traditional Hydro-meteorological Methodsmentioning

confidence: 63%

“…Table 2 indicates that the HM2 method gives PMP values 35% smaller than the HM1 method for the BL period; this could change if we also included the amplification by a wind factor in order to evaluate more possibilities, as proposed by Fernando and Wickramasuriya (2010). These authors conclude that the double-maximized HM2 method is similar to Hershfield's PMP estimation.…”

Section: Discussionmentioning

confidence: 91%

PMP and PMF estimations in sparsely-gauged Andean basins and climate change projections

Lagos-Zúñiga

Vargas

2014

Hydrological Sciences Journal

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Mixed-regime Andean basins present a complex scenario for flood analysis. In this study, we propose a methodology for incorporating orographic effects influenced by mountainous barriers in the Probable Maximum Precipitation (PMP) estimation method in sparsely-gauged basins. The proposed methodology is applied to the Puclaro Reservoir basin in Chile, which is affected by the Andes. The PMP estimations were calculated by applying statistical and hydrometeorological approaches to the baseline and climate change scenarios determined from projections of the ECHAM5 general circulation model. Temperature projections for the 2040-2065 period show that there would be a rise in the catchment contributing area that would lead to an increase in the average liquid precipitation over the basin. Temperature projections would also affect the maximization factors in the calculation of the PMP, as precipitable water content, raising it to 126.6% and 62.5% under scenarios A2 and B1, respectively; the probable maximum flood (PMF) would increase to +175.5% under the A2 scenario. These projections would affect the safety of dam design and would be generalizable to zones with similar mixed hydrology and climate change projections. We propose that the methodology presented could be also applied to basins with similar characteristics.Key words PMP; PMF; orographic effect; climate change; floods Estimations des PMP et PMF dans des bassins andins peu jaugés et projections du changement climatiqueRésumé L'analyse des crues des bassins andins de régime mixte est un sujet complexe. Dans cette étude, nous proposons une méthodologie d'intégration des effets des barrières montagneuses dans la méthode d'estimation des précipitations maximales probables (PMP) dans des bassins peu jaugés. La méthodologie proposée a été appliquée au bassin du réservoir Puclaro au Chili, qui est influencé par les Andes. Les estimations des PMP ont été calculées en appliquant des approches statistiques et hydrométéorologiques aux observations instrumentales et aux scénarios de changement climatique (2045-2065) déterminés à partir de projections du modèle de circulation générale ECHAM5. Les températures prévues pour la période 2040-2065 montrent qu'il y aurait une augmentation de la zone d'alimentation qui conduirait à une augmentation des précipitations liquides moyennes sur le bassin. Les projections de températures affecteraient également les facteurs de maximisation dans le calcul de la PMP, comme la teneur en eau précipitable, l'augmentant respectivement de 126,6% et 62,5% selon les scénarios A2 et B1; la crue maximale probable (PMF) augmentant de 175,5% selon le scénario A2. Ces projections affecteraient la sécurité du barrage et seraient généralisables à des zones pour lesquelles le régime hydrologique mixte et les projections de changement climatique sont similaires. Nous proposons que la méthodologie présentée puisse également être appliquée à des bassins de caractéristiques similaires.

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“…The conventional moisture maximization method involves only the moisture factor (e.g., moisture content or precipitable water) (Chavan and Srinivas, ). Wind, as a typical dynamic factor with easy access, is combined with the moisture maximization method to develop the MWM approach (Fernando and Wickramasuriya, ; Boota et al ., ). The MWM approach involves maximizing wind and moisture conditions that affect the occurrence of rainstorms, the moisture and wind maximization factor (MWMF) is expressed by Equation , but before use, surface dew point data corresponding to observed storms should be collected for precipitable water calculation (Fernando and Wickramasuriya, ; Boota et al ., ).

MWMF = \frac{V_{m} W_{m}}{V_{d} W_{d}}

where W d is the precipitable water corresponding to the 12‐hr persistent dew point, mm; W m is the maximum precipitable water corresponding to the highest dew point within the study duration, mm; V d is the average 12‐hr persistent wind speed for the observed storm, m/s; and V m is the maximum average observed wind speed within the study duration, m/s.…”

Section: Methodsmentioning

confidence: 99%

An improved moisture and wind maximization method for probable maximum precipitation estimation and its application to a small catchment in China

Zhou

Liang

et al. 2019

Intl Journal of Climatology

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The probable maximum flood (PMF) is the highest design criterion for major hydraulic projects whose failure might cause severe loss of life and property. The probable maximum precipitation (PMP) is the corresponding extreme design rainfall, which is defined as the theoretically greatest depth of precipitation for a given duration over a particular area under modern meteorological conditions. The moisture and wind maximization (MWM) method is widely used in deriving 24‐hr PMP. However, variables in MWM factor (e.g., maximum precipitable water and wind speed) are collected from full study durations regardless of their respective main moisture inflow directions in each year. This issue could lead to higher PMP estimates which could lead to costs in the construction of hydraulic structures. To alleviate this possible problem, an improved moisture and wind maximization (IMWM) approach is proposed based on the concept of a “wind rose diagram”, data (e.g., rainfall, wind speed, dew point) are grouped according to the main moisture inflow directions of a study catchment. Analysis shows the IMWM approach has the potential to provide lower PMPs, which would have economic implications for hydraulic designs. The storm transposition approach is applied for safety, extraordinary storms occurring in the homogeneous rainfall region are transposed to a study catchment after being maximized by the IMWM method. In addition, statistical methods, including storm formulation, trend analysis and hydrological frequency analysis, are used for deriving short‐duration PMPs. The Nash instantaneous unit hydrograph coupled with regional empirical formulas is then applied to estimate PMFs. As an example, PMP/PMF estimation approaches are applied to an important flood control project located in a small ungauged catchment of China. The study can provide a scientific basis for the construction of the study project as well as a reference for similar high‐hazard projects.

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The hydro‐meteorological estimation of probable maximum precipitation under varying scenarios in Sri Lanka

Cited by 27 publications

References 23 publications

Effects of climate change on probable maximum precipitation: A sensitivity study over the Alabama‐Coosa‐Tallapoosa River Basin

Effects of climate change on probable maximum precipitation: A sensitivity study over the Alabama‐Coosa‐Tallapoosa River Basin

PMP and PMF estimations in sparsely-gauged Andean basins and climate change projections

An improved moisture and wind maximization method for probable maximum precipitation estimation and its application to a small catchment in China

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