Observed changes in convective and stratiform precipitation in Northern Eurasia over the last five decades

Chernokulsky, А. V.; Kozlov, F. A.; Zolina, Olga; Bulygina, Olga; Мохов, И. И.; Семенов, В. А.

doi:10.1088/1748-9326/aafb82

Cited by 82 publications

(41 citation statements)

References 78 publications

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“…A recently published paper (Chernokulsky et al, 2019) presents data on changes in precipitation regime and intensity of liquid precipitation in Eurasia: a small, mostly insignificant increase in total precipitation is accompanied by a significant increase in the intensity of rainfall and an increase in the contribution of heavy rain in all regions of Russia, which directly contributes to the formation of dangerous hydrological phenomena such as flash floods. Thus, it is recognized that we need to develop new methods of calculation hydrological response under the conditions of climate change and anthropogenic impact (Maghsood et al, 2019).…”

Section: Abstract: Hydrograph Model Parametrization Runoff Formatiomentioning

confidence: 99%

Understanding hydrological processes at a remote mountainous continuous permafrost watershed in a changing environment

McLennan-Smith¹,

Nelson²,

Jovanoski³

et al. 2019

El Sawah, S. (Ed.) MODSIM2019, 23rd International Congress on Modelling and Simulation.

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This research assesses the possibility of using unique special observations data at the Suntar-Hayata station in Eastern Siberia (it was operating from 1957-1959 under the program of the International Geophysical Year) to develop and apply methods for modelling hydrological processes in the permafrost zone under conditions of poor information content to identify flow changes and understand the causes of their occurrence.

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Section: Abstract: Hydrograph Model Parametrization Runoff Formatiomentioning

confidence: 99%

Understanding hydrological processes at a remote mountainous continuous permafrost watershed in a changing environment

McLennan-Smith¹,

Nelson²,

Jovanoski³

et al. 2019

El Sawah, S. (Ed.) MODSIM2019, 23rd International Congress on Modelling and Simulation.

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“…Climate change causes significant transformation of the hydrological cycle. In many regions of Russia, the increase in the proportion and intensity of rainfall [1] is observed leading to the growth of number and magnitude of floods. Magadan region is situated in the North-East of Russia and is one of the mostly flood-prone areas of the country.…”

Section: Introductionmentioning

confidence: 99%

Reconstruction of the hazardous flood of 2014 in Magadan city based on coupled hydrometeorological modelling

et al. 2020

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The study assessed the possibility of using a deterministic distributed hydrological model Hydrograph to calculate the maximum discharge of catastrophic flood at the Magadanka River (48.5 km2, city of Magadan, North-East of Russia) in 2014. The model parameters were not calibrated but borrowed from previously performed regional modelling studies. To verify the Hydrograph model streamflow simulations with daily time step were carried out for the period 1971-2015. The median value of Nash-Sutcliffe efficiency was 0.42 for a period of 44 years, which, given the lack of a meteorological station within the catchment, made it possible to evaluate the results as satisfactory. For the catastrophic flood calculation, two types of precipitation data were used: hourly data on precipitation from the nearest weather station and distribution of precipitation for the watershed from the meteorological model WRF. The flood hydrographs were estimated for the initial and corrected sets of the model parameters. The initial set of the model parameters allowed for proper timing of the flood peak but underestimated “observed” maximum value. We introduced the decreasing correction coefficient to the infiltration parameter of the model to “stretch out” the peak and volume of hydrographs. The results have shown that combining the meteorological input from weather station and regional meteorological model may allow for successful flood simulations in ensemble mode.

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“…Owing to the diversity of contexts in which it is important, rainfall intensity has been analysed and reported using a corresponding diversity of data and methods, which can yield different characterisations of the same rainfall records. In studies of the secular changes in climate, for instance, the simple daily intensity index (SDII; [12,13]) finds wide application. This index is simply the total rainfall depth over a period such as a month or a year, divided by the number of rain days in that period; it is therefore the mean wet day rainfall.…”

Section: Introductionmentioning

confidence: 99%

Sub-Daily Rainfall Intensity Extremes: Evaluating Suitable Indices at Australian Arid and Wet Tropical Observing Sites

Dunkerley

2019

Water

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Rainfall intensity extremes are relevant to many aspects of climatology, climate change, and landsurface processes. Intensity is described and analysed using a diversity of approaches, reflecting its importance in these diverse areas. The characteristics of short-interval intensity extremes, such as the maximum 5-min intensity, are explored here. It is shown that such indices may have marked diurnal cycles, as well as seasonal variability. Some indices of intensity, such as the SDII (simple daily intensity index), provide too little information for application to landsurface processes. Upper percentiles of the intensity distribution, such as the 95th and 99th percentiles (Q95 and Q99) are used as indices of extreme intensity, but problematically are affected by changes in intensity below the nominated threshold, as well as above it, making the detection of secular change, and application to sites with contrasting rainfall character, challenging. For application to landsurface processes, a new index is introduced. This index (R Q95 ), is that intensity or rainfall rate above which 5% of the total rainfall is delivered. This index better reflects intense rainfall than does Q95 of even 5-min accumulation duration (AD) rainfall depths. Such an index is helpful for detecting secular change at an observing station, but, like Q95, remains susceptible to the effects of change elsewhere in the distribution of intensities. For understanding impacts of climate and climate change on landsurface processes, it is argued that more inclusive indices of intensity are required, including fixed intensity criteria.

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Observed changes in convective and stratiform precipitation in Northern Eurasia over the last five decades

Cited by 82 publications

References 78 publications

Understanding hydrological processes at a remote mountainous continuous permafrost watershed in a changing environment

Understanding hydrological processes at a remote mountainous continuous permafrost watershed in a changing environment

Reconstruction of the hazardous flood of 2014 in Magadan city based on coupled hydrometeorological modelling

Sub-Daily Rainfall Intensity Extremes: Evaluating Suitable Indices at Australian Arid and Wet Tropical Observing Sites

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