Provides an overview of morphologial modelling:
This thesis presents the development a generic morphological model for both structured and unstructured grid. An online coupling model frame is set up by modularizing a proven 3d hydrodynamic module, a bed state description module, a sediment transport module, a bed update module, and a vegetation population dynamic module. Since the model is embedded in the validated Delft software system, the existing hydrodynamics, water quality and bio-chemistry processes are applicable with minimum efforts in addition.
Both relevant geomorphological and ecological processes and their scales are discussed. For the morphological model, numerical algorithms are adjusted to adapt unstructured grid. An adaptable bed update algorithm and corresponding numerical schemes are analysed. Mass conservation of morphological updating is discussed. Afterwards a generic velocity integration algorithm is presented. The function of the morphological model is validated against 1) analytical solutions, such as: hump migration problem, equilibrium bed slope and sediment concentration profile and 2) flume experiments, such as trench migration.
For the bio-geomorphological extension part, relevant ecological processes and their scales are analyzed to build up the rationale to couple them with morphodynamic processes. Validations of ecological processes are against the field data in Lake Veluwe. Capability of the model has been explored for applications of two salt marsh restoration cases in United States and the large scale morphodynamics of shoreface connected radial sand ridges located in South-east China Sea.
This research designs and implements a flexible bio-geomorphological modelling platform. The validation cases show that it is capable to be a multidiscipline research tool for morphologists and ecologists / biologists.
2 Geomorphological Modeling: A literature review
3 A Generic Coastal Morphological Model
4 Validation of the Generic Coastal Morphological Model
5 Extension to Bio-geomorphological Modeling and Validation
6 Model Applications
7 Conclusions and Recommendations
Qinghua YE (Wuxue, China, 1977) studied Coastal Engineering at the Hangzhou University (now Zhejiang University) from 1994 to 1998 and graduated with first class honours (cum laude). From 1998 to 2001, he studied and graduated as an Msc in specialization of Coastal Engineering in Nanjing Hydraulic Research Institute. From 2001 to 2004, he worked as a coastal engineer in the section of River and Harbour department in Nanjing Hydraulic Research Institute. In 2004 he travelled to Delft, the Netherlands to study Hydroinformatics in UNESCO-IHE and was awarded a 2nd Msc in 2006. In 2006, he started to persue his phd in Delft hydraulics (now Deltares). From September of 2010 till now he was employed by Deltares as a consultant and researcher, first in the Hydraulic Engineering unit and later in the Deltares software centre.
His main research interests include: process-based morphology modeling; sand bank/ridge generation and evolution; stability analysis; biogeomorphology; human interference (dredging, sand mining), river meandering; bifurcation; bank erosion; bed form evolution; vegetation effects, sediment /mud transport modelling and water quality modelling.
He is also a Microsoft certified software developer in C++ and C#, a Sun certified Java programmer and a Cisco certified network associate
CRC Press eBooks are available through VitalSource. The free VitalSource Bookshelf® application allows you to access to your eBooks whenever and wherever you choose.The Bookshelf application offers access: