Mathematical Modeling of Ice Dynamics as a Decision Support Tool in River Engineering

Kolerski, Tomasz

doi:10.3390/w10091241

Cited by 14 publications

(9 citation statements)

References 35 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…The solution to the ice dynamic equation was carried out using the Smoothed Particle Hydrodynamics (SPH) method along with images implemented to land boundaries. The method, applied to dynamic river ice processes, has been described in [38].…”

Section: Numerical Modelmentioning

confidence: 99%

Mathematical Modeling of Ice Thrusting on the Shore of the Vistula Lagoon (Baltic Sea) and the Proposed Artificial Island

Kolerski

Zima

Szydłowski

2019

Water

Self Cite

View full text Add to dashboard Cite

Coastal lagoons are inland and shallow water bodies, separated from the ocean by a barrier. In cold regions, ice phenomena in shallow water coastal lagoons occur every winter season. Ice is predominantly formed on the surface due to density stratification and surface cooling. The ice dynamics in such areas are dominantly affected by winds. Water dynamics also cause ice movement, but due to the large areal scale of lagoons, the effect is usually limited to the direct vicinity of river estuaries. For open lagoons, which are connected to the sea by straits, tides will also cause significant movement of the ice inside the lagoon. Due to the limitation of ice outflow from a lagoon, ice fields will form ridges or hummocks on the shores. In this paper, the case of the Vistula Lagoon, located on the southern Baltic coast, is analyzed. Currently, the project of a new strait connecting the Baltic Sea with the Vistula Lagoon is in progress. As an effect of extensive dredging for the waterway to the port of Elblag, the material will be disposed of at a Confined Disposal Facility (CDF), which will form an artificial island. The island will be located on the western part of the lagoon, limiting the cross-section by about 20%. In consequence, ice cover pushed by winds blowing along the lagoon will create significant force action on the island banks. The DynaRICE mathematical model has been used to evaluate the ice dynamics and to determine the force produced by the ice on the coasts of the lagoon and the artificial island.

show abstract

Section: Numerical Modelmentioning

confidence: 99%

Mathematical Modeling of Ice Thrusting on the Shore of the Vistula Lagoon (Baltic Sea) and the Proposed Artificial Island

Kolerski

Zima

Szydłowski

2019

Water

Self Cite

View full text Add to dashboard Cite

show abstract

“…However, the development of modern measurement techniques such as GPS, LIDAR, satellite imaginary (e.g., Arseni, Roșu, Bocăneală, Constantin, & Georgescu, 2017; Gilles, Young, Schroeder, Piotrowski, & Chang, 2012; Jung, Kim, Kim, Kim, & Lee, 2014; Laks, Sojka, Walczak, & Wróżyński, 2017; Sampson et al, 2012; Sojka, Murat‐Błażejewska, & Wróżynski, 2012; Sojka & Wróżynski, 2013; Walczak, Sojka, & Laks, 2013) as well as modelling technologies, 1D/2D hybrid modelling, parallel processing, etc. (e.g., Brunner, 2016a; DHI, 2017; Dysarz, Wicher‐Dysarz, Sojka, & Jaskuła, 2019; Gąsiorowski, 2013; Kolerski, 2018; Szydłowski, Szpakowski, & Zima, 2013; Yin et al, 2018) has significantly reduced inaccuracies and uncertainties in these areas. In the more predictive analyses, one more factor is important, namely, the lack of knowledge about future inflows to river systems.…”

Section: Introductionmentioning

confidence: 99%

“…Another important aspect of the research presented here is the impact of deposition and erosion on the flow process. Prediction of the described process with its entire complexity requires the application of sophisticated mathematical models with several empirical or subjective assumptions (Brunner, 2016a; Kolerski, 2018; Parker, 2004; Popek, 2006; Wu, 2007). These may be additional sources of uncertainty.…”

Section: Introductionmentioning

confidence: 99%

Development of methodology for assessment of long‐term morphodynamic impact on flood hazard

Dysarz

2020

J Flood Risk Management

View full text Add to dashboard Cite

A methodology for quantification of the impact of sediment transport on flood hazard is proposed. The applied algorithm consists of several Python scripts for automation of sediment routing, hydrodynamic simulations, and geoprocessing of results. Flood hazard maps are uniquely linked with particular simulations of morphological changes in a river. Finally, the maps are stochastically processed. The proposed procedure was applied for a selected reach of the Warta river, located in Poland. Simulations were run for 6-and 12-year flow series composed randomly on the basis of historical data. The 30 flow series for each period and four functions describing the transport of sediment were treated as uncertain variables. It was assumed that the features characterising the mean sample may properly represent the sediment content in the river reach studied. The final results are presented as maps showing the probabilities of inundation. The comparison of results with literature data confirmed the significance of the impact related to sediment transport processes on the quantification of flood hazard uncertainty. The main advantages of the presented algorithm are effective management of simulations and processing of results obtained in 240 runs of the sediment routing model. K E Y W O R D S flood hazard assessment, flood mapping, modelling of sediment transport, python scripting 1 | INTRODUCTION The interactions between sediment transport and flood hazard seem to be obvious (e.g., Sear, Newson, & Brookes, 1995), yet these two processes are rarely linked together in a long-term perspective. An exception is an article by Pender, Patidar, Pender, and Haynes (2016), which also indicates the complexity of the mentioned problem. However, modern modelling tools, GIS processing systems, as well as programming languages, provide a sufficient framework for such analyses today.

show abstract

“…Generally, the uncertainty in flood inundation modeling can be categorized into seven major types: (1) topographic data, (2) hydrologic data, (3) data for preliminary estimation of roughness, (4) method applied for final roughness calibration, (5) method applied for estimation of maximum flows, (6) structure of the applied model and (7) transition of the model results to the maps (e.g., Refsgaard and Storm 1990;Cook and Merwade 2009;Calenda et al 2009;Liu and Merwade 2018). Some of the above-listed elements become less uncertain due to the development of the technology, e.g., increasing accuracy and resolution of LIDAR data for DEM elaboration (e.g., Gilles et al 2012;Sampson et al 2012;Walczak et al 2013;Laks et al 2017), involvement of satellite and remote sensing data (e.g., Jung et al 2014;Arseni et al 2017), elaboration of more detailed databases on flood events (e.g., Kundzewicz et al 2017) and broader availability of more accurate hydraulic models (e.g., Szydłowski et al 2013;Gąsiorowski 2013;Brunner 2016a;Kolerski 2018). A specific problem is the uncertainty related to the channel and floodplain roughness (e.g., Dimitriadis et al 2016;Pappenberger et al 2008;Engeland et al 2016;Liu and Merwade 2018).…”

Section: Introductionmentioning

confidence: 99%

Analysis of extreme flow uncertainty impact on size of flood hazard zones for the Wronki gauge station in the Warta river

et al. 2019

View full text Add to dashboard Cite

In this paper, the impact of maximum flow uncertainty on flood hazard zone is analyzed. Two factors are taken into account: (1) the method for determination of maximum flows and (2) the limited length of the data series available for calculations. The importance of this problem is a consequence of the implementation of the EU Flood Directive in all EU member states. The factors mentioned seem to be among the most important elements responsible for potential uncertainty and inaccuracy of the developed flood hazard maps. Two methods are analyzed, namely the quantiles method and the maximum likelihood method. The maximum flows are estimated for the Wronki gauge station located in the reach of the Warta river. This simple river system is located in the central part of Poland. The length of the available data is 44 years. Hence, the series of the lengths 40, 30 and 20 years are tested and compared with reference calculations for 44 years. The hydrodynamic model HEC-RAS is used to calculate water surface profiles in steady state flow. The Python scripting language is applied for automation of HEC-RAS calculations and processing of final results in the form of inundation maps. The number of trials for each factor is not huge to keep the presented methodology useful in practice. The chosen measure of uncertainty is the range of variability for maximum flow values as well as inundation areas. The estimated values stressed the great importance of the factors analyzed for the uncertainty of the maximum flows as well as inundation areas. The impact of the data series length on the maximum flows is straightforward; a shorter data series gives a wider range of variability. However, the dependencies between other factors are more complex. Hence, the application of methodology based on the simulation and GIS data processing for assessment of this problem seems to be quite a good approach.

show abstract

Mathematical Modeling of Ice Dynamics as a Decision Support Tool in River Engineering

Cited by 14 publications

References 35 publications

Mathematical Modeling of Ice Thrusting on the Shore of the Vistula Lagoon (Baltic Sea) and the Proposed Artificial Island

Mathematical Modeling of Ice Thrusting on the Shore of the Vistula Lagoon (Baltic Sea) and the Proposed Artificial Island

Development of methodology for assessment of long‐term morphodynamic impact on flood hazard

Analysis of extreme flow uncertainty impact on size of flood hazard zones for the Wronki gauge station in the Warta river

Contact Info

Product

Resources

About