Ethan J. Kubatko

Vitae:

Current Address: Department of Civil, Environmental and Geodetic EngineeringThe Ohio State University2070 Neil Avenue417D Hitchcock HallColumbus, OH 43210.

Phone: (614) 292-7176Fax: (614) 292-3780Electronic Mail: kubatko.3@osu.edu

Education:

Pennsylvania State University, Civil Engineering, B.S. (with honors and distinction), 1997University of Notre Dame, Civil Engineering, Ph.D., 2006

Appointments and Professional Experience:

2014 – present, Associate Professor, The Ohio State University, Columbus, OH.2008 – 2014, Assistant Professor, The Ohio State University, Columbus, OH.2006 – 2008, Postdoctoral Fellow, The Institute for Computational Engineering

and Sciences (ICES), University of Texas at Austin, Austin, TX.2000 – 2006, Graduate Research Assistant, University of Notre Dame, Notre Dame, IN.1997 – 2000, Civil Engineer, E.J. Kubatko Jr. and Associates, Kittanning, PA.

Honors and Fellowships:

• Visiting Associate Professorship, Chuo University, Tokyo, Japan, Summer 2016.• Visiting Associate Professorship, Chuo University, Tokyo, Japan, Summer 2015.• National Effective Teaching Institute nominee, 2013 (attended January 2014).• Lumley Research Award, The Ohio State University College of Engineering, recognizing “a

select group of researchers in the College of Engineering who have shown exceptional activityand success in pursuing new knowledge of a fundamental or applied nature”, 2013.

• Visiting Fellowship at the Isaac Newton Institute for Mathematical Sciences, Cambridge, UK,2012.

• Brazilian Association for Computational Methods in Engineering (ABMEC) Travel Scholarship,2012.

• The J. Tinsley Oden Faculty Fellowship Research Program, University of Texas at Austin, 2008,2009, 2010, 2011, and 2012.

• ASCE Student Chapter Professor of the Year Award, 2009.• USACM Post-Doctoral and Young Investigator Travel Award, 2008.• Department of the Army, Certificate of Appreciation, “in recognition of contributions to the

Interagency Performance Evaluation Taskforce (IPET) for hurricanes Katrina and Rita,” 2007.• ICES Postdoctoral Fellowship, University of Texas at Austin, 2006–2008.• SGI Award for Computational Science and Visualization, University of Notre Dame, 2006.• National Science Foundation Monbukagakusho Research Experience Fellowship, Tokyo Univer-

sity, Summer 2001.• Member, Chi Epsilon Society: The National Civil Engineering Honor Society.

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Research Interests:

My primary research interests are in the development, implementation, analysis, and application ofcomputational models for fluid flow and transport processes. The main goal of this research is thedevelopment and application of “next generation” high performance computing tools, which utilizestate-of-the-art methods and algorithms, that can be used to help solve a wide range of societallyrelevant problems. In the context of my own research, for example, the developed computational toolshave been used to guide improvements in coastal management practices and hazard mitigation strate-gies and to investigate the feasibility of generating renewable energy by harnessing tidal and waveenergy. The research is highly interdisciplinary in nature, involving aspects of, not only engineering,but also applied mathematics, physical oceanography and computer science.

A significant portion of my research has been in the area of high-order Runge–Kutta discontinuousGalerkin finite element methods applied to hyperbolic and advection-dominated conservation laws,with a specific focus in shallow water modeling. This work is directed towards the development of ahigh-order, fully-coupled model system for simulating problems of a multiphysics/multiscale nature(waves, currents, sediment transport, overland flow), all within a petascale (and beyond) comput-ing environment. Some of my most recent work is focused on the development of adaptive multi-physics/multidimensional modeling approaches for overland flooding that are designed to adaptivelyswitch between various models in order to simultaneously optimize physical correctness and computa-tional efficiency. The development of these types of adaptive and high-order approaches — which havenot yet been fully realized in large-scale, operational codes — along with the supporting concepts andnumerical tools that make their application to full-scale problems possible, is one of the main thrustsof my research.

Peer-reviewed Journal Articles:

1. Rahimi, M., Shafieezadeh, A., Wang, Z., Wood, D., Kubatko, E.J., Efficient Reliability Analysisof Soil Slopes Using Error Rate-Based Adaptive Kriging, Computers and Geotechnics, in review.

2. Mulamba, T., Bacopoulos, P., Kubatko, E.J., Pinto, G.F., Sea-level rise impacts on longitudinalsalinity in a low-gradient estuarine river: Lower St. Johns River and its tributaries, ClimaticChange, in review.

3. Colton, C.J., Kubatko, E.J., Nappi, A., Sebian, R., West, D., Mandlia, K.T., hp discontinuousGalerkin methods for parametric, wind-driven water wave models, Advances in Water Resources,119, pp. 70–83, 2018.

4. West, D.W., Kubatko, E.J., Conroy, C.J., Yaufman, M., Wood, D., A multidimensional discon-tinuous Galerkin modeling framework for overland flow and channel routing, Advances in WaterResources, 102, pp. 1147–1171, 2017.

5. Bacopoulos, P., Kubatko, E.J., Hagen, S.C., Cox, A.T., Mulamba, T., Modeling and data assess-ment of longitudinal salinity in a low-gradient estuarine river, Environmental Fluid Mechanics,17, pp. 323–353, 2017.

6. Michoski, C., Alexanderian, A., Dawson, C., Paillet, C., Kubatko, E.J., Stability of NonlinearConvection-Diffusion-Reaction Systems in Discontinuous Galerkin Methods, Journal of ScientificComputing, 70, pp. 516–550, 2017.

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7. Conroy, C.J., and Kubatko, E.J., hp discontinuous Galerkin methods for the vertical extent ofthe water column in coastal settings part I: barotropic forcing, Journal of Computational Physics,305, pp. 1147–1171, 2016.

8. Michoski, C., Dawson, C., Kubatko, E.J., Wiraset, D., Westerink, J.J.,A comparison of artifi-cial viscosity, limiters, and filters, for high order discontinuous Galerkin solutions in nonlinearsettings, Journal of Scientific Computing, 66(1), pp. 406–434, 2016.

9. Wirasaet, D, Brus, S.R., Michoski, C., Kubatko, E.J., Westerink, J.J., Dawson, C., Artificialboundary layers in discontinuous Galerkin solutions to shallow water equations in channels,Journal of Computational Physics, 299, pp. 597–612, 2015.

10. Kubatko, E.J., Yeager, B.A., Ketcheson, D.I., Optimal strong-stability-preserving Runge–Kuttatime discretizations for discontinuous Galerkin methods, Journal of Scientific Computing, 60,pp. 313–344, 2014.

11. Wirasaet, D., Kubatko, E.J., Michoski, C., Tanaka, S., Westerink, J.J., Dawson, C., Discontinu-ous Galerkin methods with nodal and hybrid modal/nodal triangular, quadrilateral, and polygonalelements for nonlinear shallow water flow, Computer Methods in Applied Mechanics and Engi-neering, 270, pp. 113–149, 2014.

12. Tamura, H., Bacopoulos, P., Wang, D., Hagen, S.C., Kubatko, E.J., State estimation of tidalhydrodynamics using ensemble Kalman filter, Advances in Water Resources, 64, pp. 45–56, 2014.

13. Michoski, C., Dawson, C., Mirabito, C., Kubatko, E.J., Wiraset, D., Westerink, J.J., Fullycoupled methods for multiphase morphodyanmics, Advances in Water Resources, 59, pp. 95–110,2013.

14. Dawson, C., Trahan, C.J., Kubatko, E.J., A Parallel Local Timestepping Runge–Kutta Discon-tinuous Galerkin Method with Applications to Coastal Ocean Modeling, Computer Methods inApplied Mechanics and Engineering, 259, pp. 154–165, 2013.

15. Kubatko, E.J., Yeager B.A., Maggi A.L., New computationally efficient quadrature formulas fortriangular prism elements, Computers and Fluids, 73, pp. 187–201, 2013.

16. Kubatko, E.J., Yeager B.A., Maggi A.L., New computationally efficient quadrature formulas forpyramidal elements, Finite Elements in Analysis and Design, 65, pp. 63–75, 2013.

17. Conroy, C.J., Kubatko, E.J., West, D.W., ADMESH: An advanced, automatic unstructured meshgenerator for shallow water models, Ocean Dynamics, 62, pp. 1503–1517, 2012.

18. Michoski, C., Mirabito, C., Dawson, C., Wiraset, D., Kubatko, E.J., Westerink, J.J., Dynamicp-enrichment schemes for multicomponent reactive flows, Advances in Water Resources, 34,pp. 1666–1680, 2011.

19. Michoski, C., Mirabito, C., Dawson, C., Wiraset, D., Kubatko, E.J., Westerink, J.J., Adaptivehierarchic transformations for dynamically p–enriched slope–limiting over discontinuous Galerkinsystems of generalized equations, Journal of Computational Physics, 230, pp. 8028–8056, 2011.

20. Dawson, C., Kubatko, E.J., Westerink, J.J., Trahana C., Mirabito, C., Michoskia C., Panda,N., Discontinuous Galerkin methods for modeling hurricane storm surge, Advances in WaterResources, 34, pp. 1165–1176, 2011.

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21. DuChene, M., Spagnuolo, A.M., Kubatko, E.J., Westerink, J.J., Dawson, C., A Frameworkfor Running the ADCIRC Discontinuous Galerkin Storm Surge Model on a GPU, ProcediaComputer Science, 4, pp. 2017–2026, 2011.

22. Mirabito, C., Dawson, C., Kubatko, E.J., Westerink, J.J., Bunya, S., Implementation of a dis-continuous Galerkin morphological model on two-dimensional unstructured meshes, ComputerMethods in Applied Mechanics and Engineering, 200, pp. 189–207, 2011.

23. Wiraset, D., Tanaka, S., Kubatko, E.J., Westerink, J.J, and Dawson, C., A performance com-parison of nodal discontinuous Galerkin methods on triangles and quadrilaterals, InternationalJournal for Numerical Methods in Fluids, 64, pp. 1336–1362, 2010.

24. Kubatko, E.J., Bunya S., Dawson, C., Westerink, J.J., and Mirabato C.M., A performancecomparison of continuous and discontinuous finite element shallow water models, Journal ofScientific Computing, 40, pp. 1573-7691, 2009.

25. Kubatko, E.J. Bunya, S., Dawson, C., and Westerink, J.J., Dynamic p-adaptive Runge-Kuttadiscontinuous Galerkin methods for the shallow water equations, Computer Methods in AppliedMechanics and Engineering, 198, pp. 1766-1774, 2009.

26. Bunya, S., Kubatko, E.J., Westerink, J.J., Dawson, C., and Yoshimura, S. A wetting and dryingtreatment for the Runge-Kutta discontinuous Galerkin solution to the shallow water equations,Computer Methods in Applied Mechanics and Engineering, 198 (17-20), pp. 1548-1562, 2009.

27. Kubatko, E.J, Westerink, J.J. and Dawson, C., Time Step Restrictions for Runge-Kutta Dis-continuous Galerkin Methods on Triangular Grids, Journal of Computational Physics, 227, pp.9697–9710, 2008.

28. Westerink, J.J., Luettich, R.A., Feyen, J.C., Atkinson, J.H., Dawson, C.N., Powell, M.D.,Dunion, J.P., Roberts, H.J., Kubatko, E.J., Pourtaheri, H. A basin- to channel-scale unstruc-tured grid hurricane storm surge model applied to southern Louisiana, Monthly Weather Review,135, pp. 833–864, 2008.

29. Kubatko, E.J. and Westerink, J.J., Exact discontinuous solutions of Exners bed evolution model:a simple theory for sediment bores, Journal of Hydraulic Engineering, 133, pp. 305–311, 2007.

30. Kubatko, E.J., Westerink, J.J., and Dawson, C., Semidiscrete discontinuous Galerkin methodsand stage-exceeding-order, strong-stability-preserving Runge-Kutta time discretization methods,Journal Computational Physics, 222, pp. 832–848, 2007.

31. Kubatko, E.J., Westerink, J.J. and Dawson, C., hp Discontinuous Galerkin methods for advec-tion dominated problems in shallow water flow, Computer Methods in Applied Mechanics andEngineering, 196, pp. 437–451, 2006.

32. Kubatko, E.J., Westerink, J.J. and Dawson, C., An unstructured grid morphodynamic modelwith a discontinuous Galerkin method for bed evolution, Ocean Modeling, 15, pp. 71–89, 2006.

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Funded Grants and Contracts:

[Kubatko budget share (parenthetically noted for collaborative projects)

]1. NASA, Effects of CYGNSS-derived parametric wind fields on storm surge modeling, 05/01/2018

- 04/30/2021, Kubatko (Lead PI), $445,329.

2. National Science Foundation, REU: A Novel Dynamically Coupled Storm Surge Hazard-Infrastructure Model for Effective Real-Time Risk-Informed Decision Making, 04/27/2018 –07/30/2019, Kubatko (OSU co-PI) $8,000.

3. National Science Foundation, A Novel Dynamically Coupled Storm Surge Hazard-InfrastructureModel for Effective Real-Time Risk-Informed Decision Making, 08/15/2016 – 08/15/2019, Ku-batko (OSU co-PI) $486,532.00.

4. National Science Foundation, REU: Hazards SEES: Social and Physical Sensing Enabled Deci-sion Support for Disaster Management and Response, 08/15/2015 – 07/31/2019, Kubatko (OSUco-PI) $16,000.

5. National Science Foundation, Hazards SEES: Social and Physical Sensing Enabled Decision Sup-port for Disaster Management and Response, 08/15/2015 – 07/31/2019, Kubatko (OSU co-PI)$1,975,000 ($300,379).

6. Aquaveo, Mesh generation techniques for high-order, mixed-element meshes for coastal oceanmodeling, 04/07/2015 – , $120,000.

7. National Science Foundation, Collaborative Research: Computational Methods for SimulatingComplex Coastal Watersheds and Floodplains, Kubatko (OSU PI: lead), with Dawson (U. Texas-Austin PI), 09/01/2012 – 08/31/2016, $300,000 ($135,000).

8. American Municipal Power-Ohio, A Computational Tool for Forecasting Flows on the Ohio River,Kubatko (PI), 07/01/2013 – 08/31/2016, $143,428.

9. National Science Foundation, CMG Collaborative Research: Simulation of wave-current inter-action using novel, coupled non-phase and phase resolving wave and Current Models, Kubatko(OSU PI), with Kennedy (U. Notre Dame co-PI), Westerink (U. Notre Dame PI: lead), Dawson,(U. Texas-Austin PI), 10/01/2010 – 09/30/2014, $500,044 ($91,257).

10. US Geological Survey, Generating Renewable Energy on Lake Erie with Wave Energy Converters:A Feasibility Study, Kubatko (PI), 09/01/2011 – 02/28/2014, $25,537.

11. National Science Foundation, Collaborative Research: Computational Methods for CoupledWave, Circulation, Sediment Transport and Morphological Evolution, Kubatko (OSU PI: lead),with Dawson (U. Texas-Austin PI), 09/15/2009 – 08/31/2013, $503,037 ($223,849).

12. Ohio Sea Grant/National Oceanic and Atmospheric Administration, Development and validationof a high-resolution, nearshore model for Lake Erie, Kubatko (PI), 02/01/2010 – 01/31/2014,$141,339.

13. National Science Foundation, Rapid Response: Oil Spill Transport Modeling in Shelf, Estuary,and Intracoastal Regions, Kubatko (PI), 09/01/2010 – 08/31/2012, $137,663.

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14. National Science Foundation (subcontracted through U. Texas-Austin), Collaborative Research:Hurricane Storm Surge Modeling on Petascale Computers, with Spagnuolo (Oakland U. PI),Dawson (U. Texas-Austin PI: lead), Joannes Westerink (U. Notre Dame PI), 01/01/2009 –08/31/2011, $1,603,562, ($60,626).

15. U.S. Army Corps of Engineers, Jacksonville District (subcontracted through University of CentralFlorida), Modeling circulation and salinity transport in St. Johns River, FL using discontinuousGalerkin finite element methods, 07/08/2009 – 07/31/2010, $11,361.

16. Ohio Sea Grant/National Oceanic and Atmospheric Administration, Development of an Un-structured Grid of Lake Erie for Hydrodynamic Modeling, Kubatko (PI), 06/16/2008 –01/01/2009, $10,000.

Supercomputer Allocation Grants:

1. Great Lakes Consortium for Petascale Computation, Scaling the effects of intermediate distur-bance and changes to small-scale ecosystem structure on ecosystem, hydrology, lake and weatherinteractions to the scale of the Great Lakes region, co-PI, with Gil Bohrer and Gajan Sivandran,OSU, 2013–2014, (1,000,000 computational units).

2. XSEDE allocation grants, Hurricane Storm Surge Modeling, co-PI, with Clint Dawson andJoannes Westerink, 2012–2014, (5,000,000 computational units).

Pending Grants and Contracts:

1. A unified, adaptive computational framework for coastal hydrodynamics and hydrology, NationalScience Foundation, Kubatko (OSU PI, lead), $199,775.00, pending.

Conference Presentations and Proceedings (⊗ = keynote, ⊕ = Kubatko student pre-sented):

1. Rahimi, M., Shafieezadeh, A., Wood, D., Kubatko, E.J., “Probabilistic Calibration of Hydro-Mechanical Soil Properties of Levees using Integrated Kriging Meta-Models and Likelihood Func-tion,” ASCE Engineering Mechanics Institute Conference 2018, Cambridge, MA, May 29–June1, 2018.

2. Rahimi, M., Wang, Z., Shafieezadeh, A., Wood, D., Kubatko, E.J., “Reliability Assessmentof the Piping Failure Mechanism in Levees using a Surrogate Model Based Method,” ASCEEngineering Mechanics Institute Conference 2018, Cambridge, MA, May 29–June 1, 2018.

3. Kubatko, E.J., “Requirements for achieving high-order accuracy for DG solutions of shallowwater equations in realistic coastal settings,” 2nd ASCETE Sudelfeld Summit, Workshop onadvanced numerical methods for earthquake and tsunami simulation on modern HPC systems,Bayrischzell, Germany, January 30–February 2, 2018.

4. Kubatko, E.J., Wood D., El-Khoury, O. (presented on my behalf by student Xiao, Y) , “Somerecent advances in a discontinuous Galerkinm (DG) model for storm surge simulation,” The 2ndInternational Conference on Computational Engineering and Science for Safety and Environ-mental Problems (COMPSAFE), Chengdu, China, October 15–18, 2017.

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5. ⊕ = Xiao, Y. and Kubatko, E.J., “A Local Discontinuous Galerkin Finite-Element Solutionof the Richards’ Equation,” The 2nd International Conference on Computational Engineeringand Science for Safety and Environmental Problems (COMPSAFE), Chengdu, China, October15–18, 2017.

6. ⊗ = Kubatko, E.J., “Discontinuous Galerkin (DG) methods and supporting computational toolsfor shallow water modeling,” The 16th International workshop on Multi-scale (Un)-structuredmesh numerical Modeling for coastal, shelf, and global ocean dynamics (IMUM 2017), StanfordUniversity, CA, August 29–September 1, 2017.

7. ⊕ = Xiao, Y. and Kubatko, E.J, “A Local Discontinuous Galerkin Finite-Element Method for theRichards Equation,” The 14th U.S. National Congress on Computational Mechanics, Montreal,Canada, July 17–20, 2017.

8. ⊕ = Mattioli, D., Kubatko, E.J., Zundel A., “qADMESH+: An Automatic Quadrangular andMixed-Element Mesh Generator,” The 14th U.S. National Congress on Computational Mechan-ics, Montreal, Canada, July 17–20, 2017.

9. ⊕ = Wood, D., Kubatko, E.J., Shafieezadeh, A., Rahimi, M., “Interfacing Geotechnical andHydrodynamic Models to Resolve Failure Mechanisms of Flood Control Systems under StormSurge,” The 14th U.S. National Congress on Computational Mechanics, Montreal, Canada, July17–20, 2017.

10. ⊕ = Kubatko, E.J., “Towards an Adaptive Discontinuous Galerkin Storm Surge Model,” The14th U.S. National Congress on Computational Mechanics, Montreal, Canada, July 17–20, 2017.

11. ⊗ = Kubatko, E.J., “Some recent advances in high-order discontinuous Galerkin methods forenvironmental fluid mechanics,” The 19th International Conference on Finite Elements in FlowProblems (FEF 2017), Rome, Italy, April 5–7, 2017.

12. ⊕ = Xiao, Y., Kubatko, E.J., Sivandran, G., “A Local Discontinuous Galerkin Finite-ElementMethod for the Richards Equation,” The 19th International Conference on Finite Elements inFlow Problems (FEF 2017), Rome, Italy, April 5–7, 2017.

13. ⊕ = Wood, D. and Kubatko, E.J., “Improvements in internal barrier modeling for fluid-structureinteraction models with storm surge,” The 19th International Conference on Finite Elements inFlow Problems (FEF 2017), Rome, Italy, April 5–7, 2017.

14. ⊕ = Mattioli, D., Kubatko, E.J., Zundel A., “qADMESH+: An automatic quadrangular andmixed-element mesh generator,” The 19th International Conference on Finite Elements in FlowProblems (FEF 2017), Rome, Italy, April 5–7, 2017.

15. Hanazawa, H., Ito, S., Ling, G., Kubatko, E.J., Kashiyama, K, “Shallow water flow analysis basedon DG-FEM,” Conference proceeding of the 30th Computational Fluid Dynamics Symposium,NO.144, C01-2, OS3-4 Regional Environment and Disaster Prevention (in Japanese).

16. Kubatko, E.J., Wirasaet, D., Yeager, B.A., “Discontinuous Galerkin methods on quadrilateraland hexahedral elements,” The 12th World Congress on Computational Mechanics, Seoul, Korea,July 24–29, 2016.

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17. ⊕ = Mattioli, D., Kubatko, E.J., West, D., Zundel, A., “Automatic mesh generation techniquesfor adapting triangular meshes to quadrilateral and mixed-element meshes,” The 12th WorldCongress on Computational Mechanics, Seoul, Korea, July 24–29, 2016.

18. ⊕ = Sebian, R., Kubatko, E.J., Conroy, C., “DG-WAVE: advancements and applications withalgal transport on the Great Lakes,” The 12th World Congress on Computational Mechanics,Seoul, Korea, July 24–29, 2016.

19. ⊕ = Yaufman, M.B., Kubatko, E.J., West, D., “A discontinuous Galerkin-based forecasting toolfor the Ohio River basin,” The 12th World Congress on Computational Mechanics, Seoul, Korea,July 24–29, 2016.

20. ⊕ = Wood, D., Kubatko, E.J., Overman, E., “Solving unsteady advection-diffusion problemsin one and more dimensions with local discontinuous Galerkin methods and implicit-explicitRunge-Kutta time-stepping,” The 12th World Congress on Computational Mechanics, Seoul,Korea, July 24–29, 2016.

21. Hanazawa, H., Ito, S., Kashiyama, K., Kubatko, E.J., “Tsunami wave simulations based ondiscontinuous Galerkin finite element method,” The 12th World Congress on ComputationalMechanics, Seoul, Korea, July 24–29, 2016.

22. ⊗ = Kubatko, E.J., West, D., Yaufman, M., “A multidimensional discontinuous Galerkin mod-eling framework for coupled rainfall-runoff/riverine flow,” European Congress on ComputationalMethods in Applied Sciences and Engineering, Crete Island, Greece, June 5–10, 2016.

23. ⊕ = Moran, M., Kubatk, E.J., “Integration of a Storm Surge Model into a ComputationalFramework for Crisis Mapping,” European Congress on Computational Methods in AppliedSciences and Engineering, Crete Island, Greece, June 5–10, 2016.

24. Bacopoulos, P., Mulamba, T., Kubatko, E.J., and Pinto, G.F., Poster: “Modeling and analysisof sea-level rise impacts on salinity in the lower St. Johns River (LSJR),” AGU Fall Meeting,San Francisco, December 14–18, 2015.

25. ⊗ Kubatko, E.J., “Recent progress in discontinuous Galerkin methods for shallow water andoverland flow,” Finite Elements in Flow Problems (FEF 2015), Taipei, Taiwan, March 16–18,2015.

26. ⊕ = Kubatko, E.J. and Conroy, C., “Development and validation of DGWAVE: a discontinuousGalerkin-based numerical wave prediction model,” SIAM Conference on Computational Scienceand Engineering, Salt Lake City, Utah, March 14–18, 2015.

27. ⊕ Conroy, C. and Kubatko, E.J., “Discontinuous Galerkin (DG) modified basis methods forbaroclinic flows,” 13th U.S. National Congress on Computational Mechanics, San Diego, CA,July 26–July 30, 2015.

28. Kubatko, E.J., “Some recent advances in high-order discontinuous Galerkin methods for shallowwater flow,” 13th U.S. National Congress on Computational Mechanics, San Diego, CA, July26–July 30, 2015.

29. ⊕ Sebian, R., Kubatko, E.J., and Yeager, B., “Optimal high-order, strong-stability-preservinglinear multistep time discretizations for discontinuous Galerkin methods,” 13th U.S. NationalCongress on Computational Mechanics, San Diego, CA, July 26–July 30, 2015.

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30. ⊕ West, D. and Kubatko, E.J., “A multidimensional discontinuous Galerkin modeling frameworkfor overland flow,” 13th U.S. National Congress on Computational Mechanics, San Diego, CA,July 26–July 30, 2015.

31. ⊕ Yaufman, M.B., Ross, T., Allison, C., and Kubatko, E.J., “Development and application ofa coupled rainfall-runoff/river flow model for the Ohio River,” 13th U.S. National Congress onComputational Mechanics, San Diego, CA, July 26–July 30, 2015.

32. ⊕ West, D., Conroy, C., and Kubatko, E.J., “Mesh Generation Techniques for a Multidi-mensional, Multi-Physics Modeling Framework for Coupled Shallow Water/Overland Flow,”The 13th International workshop on Multi-scale (Un)-structured mesh numerical Modeling forcoastal, shelf, and global ocean dynamics, Lisbon, Portugal, August 25–27, 2014.

33. ⊕ Conroy, C. and Kubatko, E.J., “A three-dimensional shallow water equation model using high-order discontinuous Galerkin (DG) methods,” The 13th International workshop on Multi-scale(Un)-structured mesh numerical Modeling for coastal, shelf, and global ocean dynamics, Lisbon,Portugal, August 25–27, 2014.

34. ⊕ Sebian, R., Conroy, C. and Kubatko, E.J.,“Applications of a discontinuous Galerkin-basedspectral wave model,” The 13th International workshop on Multi-scale (Un)-structured meshnumerical Modeling for coastal, shelf, and global ocean dynamics, Lisbon, Portugal, August25–27, 2014.

35. Kubatko, E.J., “A multidimensional modeling approach for coupled shallow water + overlandflow,” 11th World Congress on Computational Mechanics, Barcelona, Spain, July 20–25, 2014.

36. ⊕ Conroy, C. and Kubatko, E.J., “A high-order, three-dimensional discontinuous Galerkin (DG)coastal ocean circulation and transport,” 11th World Congress on Computational Mechanics,Barcelona, Spain, July 20–25, 2014.

37. ⊕ Sebian, R., Kubatko, E.J., Nappi, A., and Dietrich, C., “Advances in discontinuous Galerkin-based Spectral Wave Modeling,” 11th World Congress on Computational Mechanics, Barcelona,Spain, July 20–25, 2014.

38. ⊕ Yeager, B. A., and Kubatko, E. J., “Achieving efficient solutions to the shallow water equa-tions with high-order discontinuous Galerkin methods,” 11th World Congress on ComputationalMechanics, Barcelona, Spain, July 20–25, 2014.

39. ⊕ West, D., Conroy, C., and Kubatko, E.J., “Mesh Generation Techniques for a Multidimen-sional, Multi-Physics Modeling Framework for Coupled Shallow Water/Overland Flow,” 11thWorld Congress on Computational Mechanics, Barcelona, Spain, July 20–25, 2014.

40. Bacopoulos, P., Kubatko, E.J., Hagen, S.C., “2D salinity calculations for lower St. Johns Riverusing discontinuous Galerkin methods,” 11th World Congress on Computational Mechanics,Barcelona, Spain, July 20–25, 2014.

41. Kubatko, E.J., “A unified discontinuous Galerkin approach for solving the two- and three-dimensional shallow water equations,” SIAM Annual Meeting, Chicago, IL, July 7–11, 2014.

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42. Kubatko, E.J., “A unified discontinuous Galerkin approach for two- and three-dimensional shal-low water flow,” 1st ASCETE Sudelfeld Summit, Workshop on advanced numerical methodsfor earthquake and tsunami simulation on modern HPC systems, Bayrischzell, Germany, May20–23, 2014.

43. ⊗ Kubatko, E.J., West D., Conroy, C., “Computational methods for simulating complex coastalwatersheds and floodplains,” Computational Engineering & Science for Safety & EnvironmentalProblems (COMPSAFE), Sendai, Japan, April 13–16, 2014.

44. Kubatko, E.J., “SWEMmingwithGalerkin:UpdatesonDG-SWEM,” The 17th Annual ADCIRCModel Workshop, hosted by the Naval Research Laboratory at Stennis Space Center, MS, April3–4, 2014.

45. ⊕ West, D., Kubatko, E.J., “Extraction of watershed features for overland flow mesh generation,”The 12th International workshop on Multi-scale (Un)-structured mesh numerical Modeling forcoastal, shelf, and global ocean dynamics, Austin, TX, September 16–19, 2013.

46. ⊕ Yeager, B., Kubatko, E.J., “New time steppers and integration rules for discontinuous Galerkinspatial discretizations of hyperbolic equations,” The 12th International workshop on Multi-scale(Un)-structured mesh numerical Modeling for coastal, shelf, and global ocean dynamics, Austin,TX, September 16–19, 2013.

47. ⊕ Conroy, C., Kubatko, E.J., “hp Discontinuous Galerkin Methods for the Vertical Extent ofthe Water Column,” 12th U.S. National Congress on Computational Mechanics, Raleigh, NC,July 22–25, 2013.

48. ⊕ Nappi, A., Kubatko, E.J., “Development and Validation of DG WAVE: a DiscontinuousGalerkin-Based Numerical WAVe Prediction Model,” 12th U.S. National Congress on Compu-tational Mechanics, Raleigh, NC, July 22–25, 2013.

49. ⊕ West, D., Kubatko E.J., “Automatic Mesh Generation of Watersheds Using High-ResolutionDigital Elevation Maps,” 12th U.S. National Congress on Computational Mechanics, Raleigh,NC, July 22–25, 2013.

50. ⊕ Yeager, B., Kubatko E.J., “Some Efficiency Improvements for Runge–Kutta DiscontinuousGalerkin Methods,” 12th U.S. National Congress on Computational Mechanics, Raleigh, NC,July 22–25, 2013.

51. Kubatko, E.J., Dibiling, D., “Development and Application of a Discontinuous Galerkin FiniteElement Model for the Great Lakes,” 12th U.S. National Congress on Computational Mechanics,Raleigh, NC, July 22–25, 2013.

52. � Kubatko, E.J., Nappi, A., “Development of an accurate and efficient discontinuous Galerkin-based wave prediction model,” SIAM Conference on Mathematical and Computational Issues inthe Geosciences, Padova, Italy, June 17–20, 2013.

53. � Kubatko, E.J., Nappi, A., “Development and validation of a discontinuous Galerkin waveprediction model,” The Mathematics of Finite Elements and Applications, London, UK, June11–14, 2013.

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54. ⊕ Conroy C., Kubatko, E.J., “ADmesh: An Advanced Unstructured Mesh Generator for OceanModels,” The 17th Annual ADCIRC Model Workshop, U.S. Army Engineering Research andDevelopment Center, Vicksburg, MS, April 29–30, 2013.

55. ⊕ Nappi, A., Kubatko, E.J., “Introducing DG-WAVE: A discontinuous Galerkin-based wave pre-diction model,” The 17th Annual ADCIRC Model Workshop, U.S. Army Engineering Researchand Development Center, Vicksburg, MS, April 29–30, 2013.

56. � Kubatko, E.J., Yeager, B., “Optimal strong-stability-preserving Runge–Kutta methods fordiscontinuous Galerkin spatial discretizations of hyperbolic problems,” SIAM Conference onComputational Science and Engineering, Boston, MA, February 25–March 1, 2013.

57. Dawson, C., Westerink, J., Kubatko, E.J., Michoski C., Dietrich C., Meixner, J., Wirasaet D.,“Discontinuous Galerkin methods for coastal ocean models,” Finite Elements in Flow Problems,San Diego, CA, February 23–24, 2013.

58. � Kubatko, E.J., “Recent advances in discontinuous Galerkin methods for shallow water flow,”Finite Elements in Flow Problems, San Diego, CA, February 23–24, 2013.

59. Serhadlioglu, S., Houlsby, G.T., Adcock, G.T., Draper, S., Borthwick, A., Kubatko, E.J., “As-sessment of tidal stream energy resources in the UK using a discontinuous Galerkin finite elementscheme,” Finite Elements in Flow Problems, San Diego, CA, February 24–27, 2013.

60. Bacopoulos, P., Kubatko, E.J., Hagen, S.C., “2D Transport Tendencies of Floridas East CoastNearshore and Estuarine Waters,” 10th World Congress on Computational Mechanics, SaoPaulo, Brazil, July 8–13 2012.

61. ⊕ Conroy C., Kubatko, E.J., “A discontinuous Galerkin method for 3D shallow water flow,”10th World Congress on Computational Mechanics, Sao Paulo, Brazil, July 8–13 2012.

62. ⊕ Dibiling, D., Kubatko, E.J., “Development and validation of a high-resolution nearshore modelfor Lake Erie,” 10th World Congress on Computational Mechanics, Sao Paulo, Brazil, July 8–132012.

63. ⊕ Nappi, A., Kubatko, E.J., “Development and application of a discontinuous Galerkin-basedwave prediction model,” 10th World Congress on Computational Mechanics, Sao Paulo, Brazil,July 8–13 2012.

64. Kubatko, E.J., Yeager, B., “Efficient numerical integration formulas for pentahedral elements,”10th World Congress on Computational Mechanics, Sao Paulo, Brazil, July 8–13 2012.

65. ⊕ West, D., Kubatko, E.J., Conroy, C., “ADMESH: An Advanced Mesh Generator for CoastalOcean Modeling,” 10th World Congress on Computational Mechanics, Sao Paulo, Brazil, July8–13 2012.

66. ⊕ Yeager, B., Kubatko E.J., “Optimal strong-stability-preserving Runge–Kutta time discretiza-tions for discontinuous Galerkin methods,” 10th World Congress on Computational Mechanics,Sao Paulo, Brazil, July 8–13 2012.

67. Brus, S., Westerink, J., Wirasaet, D., Donahue, A., Kubatko, E.J., “Importance of Local MassConservation in Coupling Flow and Transport Models,” 3rd International Symposium on ShallowFlows, Iowa City, June 4–6, 2012.

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68. ⊕ Conroy, C., Kubatko, E.J., Poster: “Modeling of circulation and transport in the Gulf ofMexico for ninety days following the deepwater horizon oil spill,” International Workshop onMultiscale (Un)-structured Mesh Numerical Modeling, Bremerhaven, Germany, August 22–25,2011.

69. ⊕ Dibling, D., Kubatko, E.J., Poster: “Development and validation of a nearshore model forLake Erie,” International Workshop on Multiscale (Un)-structured Mesh Numerical Modeling,Bremerhaven, Germany, August 2011.

70. Kubatko, E.J., Conroy, C., “ADMESH: An advanced automatic mesh generator for shallow wa-ter models,” International Workshop on Multiscale (Un)-structured Mesh Numerical Modeling,Bremerhaven, Germany, August 22–25, 2011.

71. Bacopoulos, P., Hagen, S.C., and Kubatko, E. J., “2D salinity calculations for South AtlanticBight using discontinuous Galerkin method,” 11th U.S. National Congress on Computationalmechanics, University of Minnesota, Minneapolis, July 25–28, 2011.

72. ⊕ Conroy, C., Kubatko, E.J., Bacopolous, P., Hagen, S.C., “Modeling of circulation and trans-port in the Gulf of Mexico for 90 days following the Deepwater Horizon oil spill,” 11th U.S. Na-tional Congress on Computational mechanics, University of Minnesota, Minneapolis, July 25–28,2011.

73. Dawson, C., Westerink, J., Kubatko, E.J., Michoski, C., Mirabito, C., Dietrich, J.C., Meixner, J.,“Discontinuous Galerkin Methods for Hydrodynamics, Waves and Sediment Transport,” 11thU.S. National Congress on Computational mechanics, University of Minnesota, Minneapolis,July 25–28, 2011.

74. Kubatko, E.J., Maggi, A., “Developing a Computational Infrastructure for Mixed ElementMeshes,” 11th U.S. National Congress on Computational mechanics, University of Minnesota,Minneapolis, July 25–28, 2011.

75. Michoski, C., Mirabito, C., Dawson, C., Kubatko, E.J., Wirasaet, D., Westerink, J., “Dynamicp-Enrichment Schemes with Dynamic Slope Limiting for Multicomponent Reactive Flows,” 11thU.S. National Congress on Computational mechanics, University of Minnesota, Minneapolis,July 25–28, 2011.

76. Wirasaet, D., Kubatko, E.J., Michoski, C., Tanaka, S., Westerink, J.J., Dawson, C., “An As-sessment of Discontinuous Galerkin Methods with Nodal and Hybrid Modal/Nodal Triangular,Quadrilateral, and Polygonal Elements for Shallow Water Flows,” 11th U.S. National Congresson Computational mechanics, University of Minnesota, Minneapolis, July 25–28, 2011.

77. � Kubatko, E.J., “Recent Progress on DG-ADCIRC,” The 15th ADCIRC Model Workshop,Naval Research Laboratory, Stennis Space Center, Stennis, MS, April 18–19, 2011.

78. � Kubatko, E.J., “A sigma-coordinate, discontinuous Galerkin method for the three-dimensionalshallow water equations,” SIAM Conference on Mathematical and Computational Issues in theGeosciences, Long Beach, CA, March 21–24, 2011.

79. ⊕ Conroy, C., Kubatko, E.J., Poster: “ADMESH: An advanced automatic mesh generator forhydrodynamics models,” International Workshop on Multiscale (Un)-structured Mesh NumericalModeling, Cambridge, MA, August 17–20, 2010.

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80. Kubatko, E.J., Dawson, C, Conroy, C., Maggi, A., “A discontinuous Galerkin method for the 3dshallow water equations,” International Workshop on Multiscale (Un)-structured Mesh Numer-ical Modeling, Cambridge, MA, August 17–20, 2010.

81. ⊕ Maggi, A., Kubatko, E.J., Poster: “Discontinuous Galerkin methods for the shallow waterequations comparing triangular, quadrilateral and mixed meshes,” International Workshop onMultiscale (Un)-structured Mesh Numerical Modeling, Cambridge, MA, August 17–20, 2010.

82. ⊕ Conroy, C., Kubatko, E.J., “‘An advanced automatic mesh generator for hydrodynamic mod-els,” Joint 9th World Congress on Computational Mechanics and 4th Asian Pacific Congress onComputational Mechanics, Sydney, Australia, July 19–23, 2010.

83. Kubatko, E.J., Dawson, C, “A sigma-coordinate, discontinuous Galerkin method for the three-dimensional shallow water equations,” Joint 9th World Congress on Computational Mechanicsand 4th Asian Pacific Congress on Computational Mechanics, Sydney, Australia, July 19–23,2010.

84. Westerink, J., Wirasaet, D., Tanaka, S., Kubatko, E.J., Dawson, C., “Nodal DiscontinuousGalerkin Solutions to Shallow Water Flow and Transport on Triangles and Quadrilaterals,”Joint 9th World Congress on Computational Mechanics and 4th Asian Pacific Congress on Com-putational Mechanics, Sydney, Australia, July 19–23, 2010.

85. Wirasaet, D., Tanaka, S., Kubatko, E.J., Westerink, J., Dawson, C., “A Study on Performancesof Nodal Discontinuous Galerkin Methods on Quadrilaterals and Triangles,” 14th ADCIRCModel Workshop, U.S. Army Engineer Research and Development Center, Vicksburg, MS, April20–21, 2010.

86. Bunya, S., Kubatko, E.J., Westerink, J.J., Dawson, C., “A RKDG Shallow Water Model withan Eulerian Moving Boundary Method for Riverine and Coastal Flow Problems,” The JapanSociety for Computational Engineering and Science 2nd International Workshops on Advancesin Computational Mechanics, Yokohama, Japan, March 29–31, 2010.

87. Dawson, C., Kubatko, E.J., Westerink, J., “HPC for Hurricane Storm Surge and SedimentTransport Using Discontinuous Galerkin Methods,” The Japan Society for Computational En-gineering and Science 2nd International Workshops on Advances in Computational Mechanics,Yokohama, Japan, March 29–31, 2010.

88. � Kubatko, E.J., “Towards a sigma-coordinate, discontinuous Galerkin method for the three-dimensional shallow water equations,” The Japan Society for Computational Engineering andScience 2nd International Workshops on Advances in Computational Mechanics, Yokohama,Japan, March 29–31, 2010.

89. Bacopoulos, P., Hagen, S. C., and Kubatko, E. J., Poster: “Tidal calculations for the SouthAtlantic Bight and Atlantic Intracoastal Waterway based on a discontinuous Galerkin method,”10th U.S. National Congress on Computational Mechanics, Columbus, OH, July 16–19, 2009.

90. Kubatko, E.J., “A finite element hydrodynamic model for Lake Erie,” 10th U.S. NationalCongress on Computational Mechanics, Columbus, OH, July 16–19, 2009.

91. Mirabito, C., Dawson, C., Kubatko, E.J., Westerink, J., Bunya, S., “Implementation of a Dis-continuous Galerkin Morphological Model on Two-dimensional Unstructured Meshes,” 10th USNational Congress on Computational Mechanics, Columbus, OH, July 16–19, 2009.

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92. � Kubatko, E.J., Bunya, S., Dawson, C., Westerink, J., “Aspects of Runge-Kutta discontinuousGalerkin methods for shallow water flow and transport,” International Conference on FiniteElements in Flow Problems, Tokyo, April 1–3, 2009.

93. Westerink, J., Dietrich, C., Tanaka, S., Dawson, C., Luettich, R., Kubatko, E.J., Bunya, S.,Zijlema, M., Holthuijsen, L., Stelling, G., “Advances in Scalable High Resolution Wave andCurrent Computations,” ADCIRC Workshop, Silver Spring, MD, April 20–21, 2009.

94. � Kubatko, E.J., Bunya, S., Dawson, C., Westerink, J., “A Discontinuous Galerkin Storm SurgeModel,” SIAM Conference on Computational Science and Engineering, Miami, FL, March 2–6,2009.

95. � Kubatko, E.J., Dawson, C., “Towards a discontinuous Galerkin based storm surge model,” TheEighth International Conference on Hydro-Science and Engineering, Nagoya, Japan, September8–12, 2008.

96. Bunya, S., Kubatko, E.J., Westerink, J.J., Dawson C., Serhadhoglu, S., “A RKDG ShallowWater Model for Coastal and Riverine Flow Problems Containing Wetting and Drying Zones,”International Workshop on Unstructured Grid Numerical Modeling of Coastal, Shelf and OceanFlows, Halifax, Canada, September, 2008.

97. Dawson, C., Proft, J., Westerink, J., Tanaka, S., Kubatko, E.J., Bunya, S., “A ComparativeStudy of Continuous and Discontinuous Finite Element Methods for the Shallow Water Equa-tions,” Seventh International Workshop on Unstructured Grid Numerical Modelling of Coastal,Shelf, and Ocean Flows, Dartmouth, Nova Scotia, September 17–19, 2008.

98. � Kubatko, E.J., “CFL Conditions for Runge–Kutta and multi-step discontinuous Galerkinmethods,” The 8th World Congress on Computational Mechanics, Venice, Italy, June 30–July4, 2008.

99. Dawson, C. and Kubatko, E.J., “Stage-Exceeding Order SSP Time-stepping for Runge–KuttaDiscontinuous Galerkin Methods,” SIAM Annual Meeting, San Diego, July 7–11, 2008.

100. Dawson,C., Westerink, J., Kubatko, E.J., Proft, J., Mirabito, C., “Parallel Finite Element Mod-els for Hurricane Storm Surges,” Teragrid 2008 Conference, Las Vegas, NV, June 9–13, 2008.

101. � Kubatko, E.J., “Progress with ADCIRC-DG,” The 12th ADCIRC Model Workshop, NavalResearch Laboratory, Oceanography Division, Stennis Space Center, MS, April 16–17, 2008.

102. Westerink, J., Bunya, S., Dietrich, C., Kubatko, E.J., Dawson, C., Luettich, R. “Modeling Hur-ricane Storm Surge along the Gulf Coast in the Wake of Katrina: Towards Petaflop Computa-tions,” Third Asian Pacific Congress on Computational Mechanics in conjunction with EleventhInternational Conference on Enhancement and Promotion of Computational Methods in Engi-neering and Science, Kyoto, Japan, December 3–6, 2007.

103. Dawson, C., Kubatko, E.J., Westerink, J., “High Performance Computing to Resolve Propaga-tion and Advection Dominated Multi-Scale Multi-Process Physics,” 10th International Workshopon Wave Hindcasting and Forecasting and Coastal Hazard Symposium, Oahu, Hawaii, November11–16, 2007.

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104. Bunya, S., Dawson, C., Kubatko, E.J., Westerink, J., Yoshimura, S., “Validation of a MovingBoundary RKDG Method for the Shallow Water Equations,” The 9th U.S. National Congresson Computational Mechanics, San Francisco, CA, July 22–26, 2007.

105. � Kubatko, E.J., Bunya, S., Dawson, C., Westerink, J., “Verification and validation of a discon-tinuous Galerkin model for shallow water flow and transport,” The 9th U.S. National Congresson Computational Mechanics, San Francisco, CA, July 22–26, 2007.

106. Westerink, J., Atkinson, J. , Bunya, S., Dawson, C., Dietrich, J.C., Kubatko, E.J., Luettich,R., Westerink, H., “Modeling Hurricane Storm Surge along the Gulf Coast — Toward PetaflopComputations,” The 9th U.S. National Congress on Computational Mechanics, San Francisco,CA, July 22–26, 2007.

107. Dawson, C. and Kubatko, E.J., “Discontinuous Galerkin Methods for Coastal Hydrodynamics,”ADCIRC Users Group Workshop, Engineering Research and Development Center, Vicksburg,MS, May 2007.

108. Bunya, S., Westerink, J., Kubatko, E.J., Dawson, C., “Mass Conservative Wetting and DryingAlgorithm for Discontinuous Galerkin Solutions to the Shallow Water Equations,” The FifthInternational Workshop on Unstructured Grid Numerical Modelling of Coastal, Shelf, and OceanFlows, Miami, FL, November 13–15, 2006.

109. Kubatko, E.J., Dawson, C., Westerink, J., “hp-adaptive discontinuous Galerkin methods for theshallow water equations,” The Fifth International Workshop on Unstructured Grid NumericalModelling of Coastal, Shelf, and Ocean Flows, Miami, FL, November 13–15, 2006.

110. Bunya, S., Westerink, J., Kubatko, E.J., Dawson, C., Yoshimura, S., “A New Wetting andDrying Algorithm for Discontinuous Galerkin Solutions to the Shallow Water Equations,” The7th World Congress on Computational Mechanics, Los Angeles, CA, July 16–22, 2006.

111. Dawson, C., Westerink, J., Kubatko, E.J., “A DG-Based Hydrodynamic Storm Surge Model,”The 7th World Congress on Computational Mechanics, Los Angeles, CA, July 16–22, 2006.

112. Kubatko, E.J., Westerink, J., Dawson, C., “High-order discontinuous Galerkin methods foradvection dominated shallow water hydrodynamics and transport,” The 7th World Congress onComputational Mechanics, Los Angeles, CA, July 16–22, 2006.

113. Kubatko, E.J., Westerink, J., Dawson, C., Bunya, S., “Developments in the discontinuousGalerkin algorithm,” Tenth ADCIRC Model Workshop, National Oceanic and Atmospheric Ad-ministration (NOAA), Silver Spring, MD, March 2006.

114. Westerink, J.J., Kubatko, E.J., Bunya, S., Dawson, C., Luettich, R.A., “Coupled Shallow WaterEquation – Morphological Computations Using Continuous Galerkin and Discontinuous GalerkinBased Finite Element Solutions,” The Fourth International Workshop on Unstructured GridNumerical Modeling of Coastal, Shelf and Ocean Flows, Bremerhaven Germany, October 10–12,2005.

115. Kubatko, E.J., Bunya, S., Westerink, J.J., Dawson, C., “Recent developments and applicationsof an hp-discontinuous Galerkin model for shallow water flow and transport,” The Fourth In-ternational Workshop on Unstructured Grid Numerical Modeling of Coastal, Shelf and OceanFlows, Bremerhaven Germany, October 10–12, 2005.

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116. Kubatko, E.J., Westerink, J.J., and Dawson, C.,“hp Discontinuous Galerkin methods for shal-low water hydrodynamics and transport,” Eighth U.S. National Congress on ComputationalMechanics, Austin, TX, July 24–28, 2005.

117. Kubatko, E.J., Westerink, J.J., and Dawson, C., “hp Discontinuous Galerkin methods for coastaland estuarine circulation, morphology change, and transport,” IMS-ADCIRC Workshop, U.S.Army Engineering Research and Development Center, Vicksburg, MS, June 2005.

118. Kubatko, E.J., Westerink, J.J., and Dawson, C., “Discontinuous Galerkin methods for coastaland estuarine circulation, morphology change, and transport,” CIRP-NCCHE CoordinationMeeting, University of Mississippi, Oxford, MS, June 2005.

119. Kubatko, E.J., Westerink, J.J., and Dawson, C., “hp-discontinuous Galerkin methods for coastaland estuarine circulation and transport,” International Workshops on Advances in Computa-tional Mechanics, Tokyo, Japan, November 3–6, 2004.

120. Westerink, J.J., Feyen, J.C. , Atkinson, J.H., Luettich, R.A., Dawson, C., Roberts, H.J., Ku-batko, E.J., “Development of a Large Domain Finite Element Storm Surge Model for SouthernLouisiana,” International Workshops on Advances in Computational Mechanics, Tokyo, Japan,November 3–6, 2004.

121. Kubatko, E.J., Westerink, J.J., and Dawson, C., “The hp-discontinuous Galerkin method ap-plied to the shallow water equations,” The Third International Workshop on Unstructured GridNumerical Modeling of Coastal, Shelf and Ocean Flows, Toulouse, France, September 20–22,2004.

122. Westerink, J., Kubatko, E.J., Dawson, C., “An unstructured grid morphodynamic model with adiscontinuous Galerkin method for bed evolution,” The 3rd International Workshop on Unstruc-tured Grid Numerical Modelling of Coastal Shelf and Ocean Flows, Toulouse, France, September20–22, 2004.

123. “An overview of IMS-ADCIRC: A system of CG and DG based solutions for 2D and 3D hydro-dynamics and transport,” Inlet Modeling System Workshop, U.S. Army Engineering Researchand Development Center, Vicksburg, MS, November 2004.

124. Kubatko, E.J., Westerink, J., Dawson, C., “Development of a Discontinuous Galerkin F.E. Modelfor Sediment Transport,” Eighth International Conference on Estuarine and Coastal Modeling,Monterey, CA, November 3–5, 2003.

125. Kubatko, E.J., Westerink, J., Dawson, C., Poster: “Modeling Transport Processes with the Dis-continuous Galerkin Method,” Coastal Ocean Modeling Gordon Conference 2003, New London,NH, June 22–27, 2003.

126. Kubatko, E.J., Westerink, J., Feyen, J., “Developments in Discontinuous Galerkin Methods forSediment Transport Models,” Fourth Annual Coastal Inlets Research Program (CIRP) StudentSeminar, Clearwater Beach FL, May 2003.

127. Kubatko, E.J., Westerink, J., “Applying the Discontinuous Galerkin Method to the Equationof Sediment Continuity,” Twelfth International Conference on Finite Element Methods in FlowProblems, Meijo University, Nagoya, Japan, April 2–4, 2003.

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128. Kubatko, E.J., Westerink, J., Feyen, J., “Solutions to the Shallow Water and Transport Equa-tions,” Third Annual Coastal Inlets Research Program (CIRP) Student Seminar, U.S. ArmyEngineering Research and Development Center, Vicksburg, MS, June 2002.

129. Kubatko, E.J., “Dynamics of a rocking structure,” Natural Hazard Mitigation Program in Japan(NHMJ) Student Seminar, Tokyo Institute of Technology, Tokyo, Japan, June 2001.

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Invited Seminar Presentations:

1. Recent efforts and advancements in the development of a discontinuous Galerkin model for stormsurge simulation,” Chuo University (Toykyo, Japan), October 2017.

2. University of Oxford, Department of Engineering Science, “Discontinuous Galerkin methods andsupporting computational tools for environmental fluid dynamics modelling,” May 2017.

3. University of East Anglia, Applied Maths Research Seminar, “Discontinuous Galerkin methodsand supporting computational tools for environmental fluid dynamics modelling,” May 2017.

4. Imperial College London, Applied Modelling and Computational Group (AMCG) Seminar, “Dis-continuous Galerkin methods and supporting computational tools for environmental fluid dy-namics modelling,” April 2017.

5. University of Texas at Austin, The Institute for Computational Engineering and Sciences, “Amultidimensional discontinuous Galerkin modeling framework for coupled rainfall-runoff/riverineflow,” February 2017.

6. Kyushu University, Japan Society of Civil Engineers Applied Mechanics Forum, “Computationaltools for environmental fluids dynamics modeling,” September 2016.

7. Nippon Koei Co., Ltd. (Toykyo, Japan), “Computational tools for environmental fluids dynamicsmodeling, with applications for hurricane storm surge and the Great Lakes,” September 2016.

8. Chuo University (Toykyo, Japan), Lecture series at the Computational Mechanics Laboratory,September 2016.

9. Chuo University (Toykyo, Japan), Lecture series at the Computational Mechanics Laboratory,June 2015.

10. University of Notre Dame, Environmental Fluid Dynamics Seminar, “Discontinuous Galerkin(DG) methods and supporting computational tools for environmental fluid dynamics modeling,”November 2014.

11. Oakland University, Department of Mathematics and Statistics, Mathematics Colloquium,Rochester, MI, “Recent advances in modeling coastal ocean currents and waves in two- andthree-dimensions using finite element methods,” October 2013.

12. The Ohio State University Environmental Science Graduate Program Seminar, Columbus, OH,“Computational Modeling: From the worlds oceans to the small intestine,” February 2013.

13. University of Central Florida Coastal Hydroscience Analysis, Modeling, and Predictive Simula-tions Laboratory Seminar, Orlando, FL, “Discontinuous Galerkin (DG) Methods for Hydrody-namics and Transport,” May, 2012.

14. The Ohio State University Applied Math Seminar, Columbus, OH, “hp discontinuous Galerkinmethods for shallow water flow and transport,” November 2011.

15. University of Minnesota, Institute for Mathematics and Its Applications (IMA), Minneapolis,MN, Societally Relevant Computing Workshop (invited attendee), April 2011.

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16. The Ohio State University Science Cafe, Columbus, OH, “Predicting the Impact of NaturalDisasters with the Help of Computational Modeling,” December 2010.

17. Oxford University, Department of Engineering Science, Oxford, UK, “Discontinuous GalerkinMethods for Hydrodynamics and Transport,” September 2010.

18. Society of Underwater Technology Group on Environmental Forces (SUTGEF), London, Eng-land, “hp discontinuous Galerkin methods for shallow water flow and transport,” September2010.

19. Kiwanas Club, Columbus, OH,“Computational Modeling for predicting natural disasters,”September 2010.

20. Oakland University, Department of Mathematics and Statistics, Mathematics Colloquium,Rochester, MI, “Discontinuous Galerkin methods for storm surge modeling,” June 2009.

21. Ohio Lake Erie Commission Quarterly Meeting, Columbus, OH, “Hydrodynamic Modeling inLake Erie,” March 2009.

22. The Water Management Association of Ohio Luncheon Seminar Series, Columbus, OH, “Design-ing the next generation of hurricane storm surge models,” October 2008.

23. The Ohio State University Dean’s Seminar Series, College of Engineering, Columbus, OH, “Com-putational Modeling: From the Gulf of Mexico to the small intestine,” September 2008.

24. Oakland University, Department of Mathematics and Statistics, Mathematics Colloquium,Rochester, MI, “hp discontinuous Galerkin methods for shallow water hydrodynamics and trans-port” June 2008.

25. University of Central Florida, Department of Civil and Environmental Engineering, Orlando,FL, “hp Discontinuous Galerkin methods for shallow water hydrodynamics and transport,” May2008.

Students’ Conference Travel Awards (Kubatko advisor):

1. Dominik Mattioli, OEE Travel Award from OSU’s Office of Energy and Environment (OEE)to attend the 19th International Conference on Finite Elements in Flow Problems, Rome, Italy,2017.

2. Dominik Mattioli, Conference Travel Award from the US Association for Computational Me-chanics to attend the 14th U.S. National Congress on Computational Mechanics, Montreal,Canada, July 2017.

3. Dylan Wood, OEE Travel Award from OSU’s Office of Energy and Environment (OEE) to attendthe 19th International Conference on Finite Elements in Flow Problems, Rome, Italy, 2017.

4. Yilong Xiao, OEE Travel Award from OSU’s Office of Energy and Environment (OEE) to attendthe 19th International Conference on Finite Elements in Flow Problems, Rome, Italy, 2017.

5. Yilong Xiao, Travel Award from OSU’s Department of CEGE to attend the 19th InternationalConference on Finite Elements in Flow Problems, Rome, Italy, 2017.

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6. Dominik Mattioli, Conference Travel Award from the US Association for Computational Mechan-ics to attend the 12th World Congress on Computational Mechanics, Seoul, Korea, July 2016 .

7. Rachel Sebian, Conference Travel Award from the US Association for Computational Mechanicsto attend the 12th World Congress on Computational Mechanics, Seoul, Korea, July 2016 .

8. Mariah Yaufman, Conference Travel Award from the US Association for Computational Mechan-ics to attend the 12th World Congress on Computational Mechanics, Seoul, Korea, July 2016 .

9. Dylan Wood, Conference Travel Award from the US Association for Computational Mechanicsto attend the 12th World Congress on Computational Mechanics, Seoul, Korea, July 2016 .

10. Dustin West, Conference Travel Award from the US Association for Computational Mechanicsto attend the 13th U.S. National Congress on Computational Mechanics, San Diego, CA, July2015.

11. Colton Conroy, Conference Travel Award from the US Association for Computational Mechanicsto attend the 11th World Congress on Computational Mechanics, Barcelona, Spain, July 2014.

12. Colton Conroy, Conference Travel Award from the US Association for Computational Mechanicsto attend the 12th US National Congress on Computational Mechanics, July 2013.

13. Benjamin Yeager, Conference Travel Award from the US Association for Computational Me-chanics to attend the 12th US National Congress on Computational Mechanics, July 2013.

14. Colton Conroy, Conference Travel Award from the US Association for Computational Mechanicsto attend the 10th World Congress on Computational Mechanics, Sao Paulo, Brazil, July 2012.

15. Angela Nappi, Conference Travel Award from the US Association for Computational Mechanicsto attend the 10th World Congress on Computational Mechanics, Sao Paulo, Brazil, July 2012.

16. Colton Conroy, Conference Travel Award from the US Association for Computational Mechanicsto to attend the 9th World Congress on Computational Mechanics, 4th Asian Pacific Congresson Computational Mechanics, Sydney, Australia, July 2010.

Academic Advisors:

Joannes Westerink (Ph.D.) and Clint Dawson (Post-doctoral).

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TEACHING/MENTORING:

• Courses Taught: SEI = Student Evaluation of Instruction on scale of 1 (lowest) to 5 (highest).

1. CIVIL EN 3130 (413): Fluid Mechanics

◦ AU 2017, 90 students, Overall SEI rating: 4.8/5.0◦ SP 2016, 113 students, Overall SEI rating: 4.9/5.0◦ AU 2015, 122 students, Overall SEI rating: 4.8/5.0◦ AU 2014, 125 students, Overall SEI rating: 4.8/5.0◦ AU 2013, 81 students, Overall SEI rating: 5.0/5.0◦ AU 2012, 111 students, Overall SEI rating: 5.0/5.0◦ AU 2011, 123 students, Overall SEI rating: 4.8/5.0◦ WI 2011, 54 students, Overall SEI rating: 4.6/5.0◦ AU 2010, 150 students, Overall SEI rating: 4.7/5.0◦ AU 2009, 139 students, Overall SEI rating: 4.6/5.0◦ AU 2008, 127 students, Overall SEI rating: 4.8/5.0

Course development: The main objective of this course is to have students develop anunderstanding of the properties of fluids and the principles of fluid static and dynamic behavior,with application of this knowledge to solving practical problems, particularly those arisingin civil engineering. In support of meeting this objective, I have developed a full set offill-in-the-blank style course notes, i.e., notes that are partially completed with blanks for thestudent to fill-in during lecture. Student evaluation of instruction (SEI) feedback has beenoverwhelmingly positive with respect to this approach, with students commonly indicating thenotes provide a good balance between staying actively engaged by taking notes and having theopportunity to listen and absorb the lecture material. These notes have also been refined overthe years based on SEI feedback, with one particular example being the incorporation of morein-class examples to the notes (these comments, and the subsequent changes in the notes toaddress them, resulted from the fact that weekly class recitations and teaching assistants wereeliminated from the course by the Department in 2009).

The students are required to apply the concepts covered in lecture, which are presented withphysical meaning and analytical support, to homework sets that form the basis of weekly quizzesand three exams that are given over the course of the semester. In addition to the lectures,quizzes and exams, there are also two laboratory experiments that I run during the semester; oneon energy conservation principles by analysis of a venturi meter; and one on momentum/energyconservation principles via analysis of a jet impacting a surface. A “mini-project” is associatedwith each lab, which consists of a series of questions and problems related to the laboratoryexperiments. Each student is required to submit a report upon project completion. The reportsare technical documents, presenting first, the logic that each student used to reach the answersto the problems assigned, second the answers to the assigned problems and finally, conclusionsand/or recommendations. Student feedback has indicated that the labs provide a good physicalexample of the application of the equations they are taught in the lecture material. Finally,at the end of the semester, I provide the students with a complete set of notes that I havedeveloped for a PE (Professional Engineering) Exam review course in water resources and showthem how the basic fluid mechanic knowledge obtained from their first course in the area canbe applied to solve actual problems from the PE exam.

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2. CIVIL EN/MECH ENG 5168 (768): Introduction to the Finite Element Method

◦ SP 2018, 10 students, Overall SEI rating: 4.5/5.0 (CE)◦ SP 2015, 41 students, Overall SEI rating: 4.8/5.0 (CE)◦ SP 2013, 72 students, Overall SEI rating: 4.8/5.0 (CE)◦ SP 2012, 44 students, Overall SEI rating: 4.5/5.0 (CE), 4.4 (ME)◦ SP 2011, 20 students, Overall SEI rating: 4.7/5.0 (CE)◦ SP 2010, 19 students, Overall SEI rating: 4.7/5.0 (CE), 4.9/5.0 (ME)◦ SP 2009, 17 students, Overall SEI rating: 4.9/5.0 (CE), 4.8/5.0 (ME)

Course development: A complete set of course notes and exercises has been developed withthe objective of introducing the basic concepts, formulation and application of finite elementmethods (FEM) to both upper-level undergraduate and graduate students from a wide rangeof academic disciplines and interests. The course is designed to be a concise introduction tothe subject, emphasizing the salient features of the method, with enough detail presented toprovide a solid foundation for more advanced courses and/or research in the area of FEM.

The course has a strong project-based theme to it, with a significant coding aspect that startswith the students modifying and expanding FEM functions and “toolboxes” provided to them,which I have written, and moves into the students writing their own. These various functionsand toolboxes are brought together over the course of the semester to build a working FEMcode used in the final course project, where the developed codes are used to solve and analyzea number of problems.

The course had historically been taught at OSU in the Department of Mechanical and AerospaceEngineering from a “stress analysis” point of view. In my own development of the course, a“broader-view” approach to FEM has been taken that led to a steady increase in both class sizeand student diversity, with class size, at one point, more than quadrupling since the first courseoffering (which initially consisted mainly of structural engineering students) and with studentsnow coming from a variety of engineering disciplines including civil, environmental, mechanical,nuclear, aerospace, industrial, and biomedical, as well as mathematics and environmental science.

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3. CIVIL EN/ENVENG 5230 (723): Transport Phenomena in Water Resources Engineering

◦ SP 2018, 32 students, Overall SEI rating: 4.8/5.0◦ SP 2016, 17 students, Overall SEI rating: 4.9/5.0◦ SP 2014, 25 students, Overall SEI rating: 4.9/5.0◦ WI 2012, 17 students, Overall SEI rating: 4.6/5.0◦ WI 2010, 9 students, Overall SEI rating: 4.8/5.0

4. CIVIL EN/ENVENG 6230 (823): Numerical Methods in Water Resources Engineering

◦ SP 2015, 6 students, Overall SEI rating: 5.0/5.0◦ SP 2013, 8 students, Overall SEI rating: 4.8/5.0◦ WI 2011, 6 students, Overall SEI rating: 4.8/5.0

Course development: This sequence of courses effectively integrates and expands on thematerial covered in my other two courses with respect to fluid mechanics and numericalmethods. For graduate students, the two courses are meant to be taken as a sequence.For undergraduate students, CE 5230 can be taken as a stand-alone technical elective forthose with a strong interest in fluid mechanics (CE 6230 is a graduate-level course). I havedeveloped full sets of course notes, exercises, exams and project-related material for both courses.

In CE 5230, the lecture material and homework assignments aim to have the students developa deeper understanding of the fluid mechanics basics obtained in CE 3130, with a focus onunderstanding the mechanisms by which momentum, heat and mass are transported in fluidsystems of interest to water resources engineers. Concepts are presented with physical meaningand a more rigorous level of analytical development than the first fluids course, recognizingthat a deeper level of understanding results from a careful analysis of the governing differentialequations.

In the second course in the sequence, CE 6230, the course material and project-related activitiesare centered on helping students acquire the skills that are essential to develop, implement, ana-lyze, and successfully use numerical methods for solving the types of partial differential equationsencountered in water resources engineering. This first requires a reasonable understanding of themathematical structure of the equations (partially obtained in CE 5230), followed by a detailedinvestigation of the general tools used in solving them numerically. Like CE 5168, the coursehas a strong project-based theme to it, which mainly consists of the students implementing var-ious numerical methods in working computer codes and the use of existing models to performsimulations.

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• Academic mentoring:

– BS Honors Advisor:

1. Rachel Sebian, Thesis: “SWAN vs DG WAVE: A Comparison of Numerical Wave PredictionModels,” 2013.

2. Dustin West, Thesis: “ADMESH: A Graphical User Interface for an Advanced Mesh Gener-ator for Coastal Ocean Modeling,” 2012.

3. Gary Margelowsky (co-advisor with Diane Foster), “Characterization of seabed geometry ina freesurface wave environment,” 2009.

– MS Advisor

1. Dominik Mattioli, 2015 – 2017.2. Dylan Wood (co-advisor with Edward Overman), 2014–2016, MS Thesis: “Solving Un-

steady Convection-Diffusion Problems in One and More Dimensions with Local DiscontinuousGalerkin Methods and Implicit-Explicit Runge-Kutta Time Stepping ,” 2016.

3. Mariah Yaufman, 2014 – 2016, MS Thesis: “A discontinuous Galerkin-based model for theOhio River,” 2016.

4. Rachel Sebian, 2014 – 2016, MS Thesis: “New transport capabilities and timesteppers for adiscontinuous Galerkin wave model,” 2016.

5. Cody Allison, 2013 – 2016, Plan B MS6. Dustin West, 2012 – 2015, MS Thesis: “A multidimensional discontinuous Galerkin modeling

framework for overland flow and channel routing,” 2015.7. Russel Stech, 2013 – 2014, Plan B MS8. Angela Nappi, 2011 – 2013, MS Thesis: “Development and application of a discontinous

Galerkin-based wave prediction model,” 2013.9. Benjamin Yeager, 2011 – 2014, MS Thesis: “Efficiency improvements for discontinuous

Galerkin finite element discretizations of hyperbolic conservation laws,” 2014.10. David Dibling, MS Thesis: “Development and validation of high-resolution, nearshore model

for Lake Erie,” 2012.11. Min Wang, 2009 – 2011, Plan B MS.12. Colton Conroy, Thesis: “ADMESH: An advanced mesh generator for hydrodynamic models,”

2011.13. Ashley Maggi, Thesis: “Discontinuous Galerkin methods for shallow water flow: Developing

a computational infrastructure for mixed element meshes,” 2011.14. Donya Frank (co-advisor with Diane Foster), “Wave-Current Bottom Boundary Layer Inter-

actions,” 2009.

– PhD Advisor:

1. Dylan Wood, 2016 – present.

2. Yilong, Xiao, 2016 – present.

3. Colton Conroy, Presidential Fellow, 2011 – 2014Current Affiliation, Department of Applied Math and Physics, Columbia University, NY

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– Postdocs supervised:

1. Omar El-Khoury, 2017 – present.

– Dissertation Committee Member

1. Jiayong Liang, OSU, current.

2. Mohammad Hossein (Mehran) Rafiei, OSU, 2017.

3. Mariantonieta Gutierrez Soto, OSU, 2017.

4. Golnazalsadat Mirfenderesgi, OSU, 2017.

5. Mehran Rafiei, OSU, 2016.

6. Mark Hope, U. Notre Dame, 2015.

7. Efthalia Chatziefstratiou, OSU, 2014

8. Bradley Doudican, OSU, 2013

9. Kyle Maurer, OSU, 2013

10. Muhammad Lodhi, OSU, 2012

11. Rosanne Martyr, U. Notre Dame, 2012

– MS Thesis Committee Member

1. Iti Patel, OSU, 2016.

2. Yilong Xiao, OSU, 2016.

3. Matthew Shilling, OSU, 2014.

4. Gordon Zuboski, OSU, 2013

5. Daniel Morone, OSU, 2012

6. Peter Amaya, OSU, 2012

7. Margaret Kociecki, OSU, 2012

8. Mariantonieta Soto, OSU, 2012

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9. Amy Coffield, OSU, 2012

10. Kevin Giriunas, OSU, 2012

11. Kyle Maurer, OSU, 2011

12. Dekel Shlomo, OSU, 2011

13. Kunpeng Zhu,OSU, 2011

14. James Howdyshell, OSU, 2010

15. Anthony Bova, OSU, 2010

16. Qing Ye, OSU, 2010

– BS Thesis Committee Member

1. Yilong Xiao, OSU, 2014.

2. Natalie Sakian, OSU, 2014.

3. Russel Stech, OSU, 2013.

– Faculty advisor, Chi Epsilon: National Civil Engineering Honor Society, 2008 – present.– Faculty mentor, Louis Stokes Alliances for Minority Participation (LSAMP) Program, 2013 –

2016.

SERVICE:

• Committee Service:

– College Faculty Professional Leave Committee (2018).– The Committee on Core Curriculum, Teaching and Learning (2017– ).– Graduate Studies Committee (2017– ).– CEGE Executive Committee (2017– ).– Resilient Infrastructure Search Committee (2017– ).– Hydrology Faculty Search Committee (2017– ).– Geodetic Hire Search Committee (2015–2016).– Graduate Studies Committee (2014–2016).– Infrastructure Hire Search Committee (2014–2015).– Professor of Practice Hire Search Committee (2012–2013).– Department Chair Search Committee (2012).– Ad-hoc Faculty Workload Committee (2012).– Graduate Studies Committee (2011–2012).

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– Hydrodynamics Faculty Search Committee (2011).

• Professional Societies:

– Member, American Society for Engineering Education (ASSE).– Member, Society for Industrial and Applied Mathematics (SIAM).– Member, US Association for Computational Mechanics (USACM)– Member, International Association for Computational Mechanics (IACM).

• Conference Minisymposia and Workshops Organized:

1. Co-organizer, Minisymposium on Computational methods in environmental fluid mechanics, The13th US National Congress on Computational Mechanics, Montreal, Canada, July 2017 .

2. Co-organizer, Minisymposium on Environmental fluid mechanics, The 19th International Con-ference on Finite Elements in Flow Problems, Rome, Italy, April 2017 .

3. Co-organizer, Minisymposium on Computational methods in environmental fluid mechanics, The12th World Congress on Computational Mechanics, Seoul, Korea, July 2016 .

4. Co-organizer, Minisymposium on Computational methods in environmental fluid mechanics,European Congress on Computational Methods in Applied Sciences and Engineering, CreteIsland, Greece, June 2016 .

5. Co-organizer, Minisymposium on Finite element methods and high performance computing forenvironmental fluid mechanics, The 12th US National Congress on Computational Mechanics,San Diego, CA, July 2015.

6. Co-organizer, Minisymposium on Computational Methods for Water Environmental Problemsand Coastal/Flood Disaster Mitigation, Computational Engineering and Science for Safety andEnvironmental Problems (COMPSAFE 2014), Sendai, Japan, April 2014.

7. Co-organizer, Minisymposium on Finite element methods and high performance computingfor environmental fluid mechanics, The 11th World Congress on Computational Mechanics,Barcelona, Spain, July 2014.

8. Co-organizer, The 12th International workshop on Multi-scale (Un)-structured mesh numericalModeling for coastal, shelf, and global ocean dynamics, Austin, TX, September, 2013.

9. Co-organizer, Minisymposium on Finite element methods and high performance computing forenvironmental fluid mechanics, The 12th US National Congress on Computational Mechanics,Raleigh, NC, July 2013.

10. Co-organizer, Minisymposium on Finite element methods and high performance computing forenvironmental fluid mechanics, The 10th World Congress on Computational Mechanics, SaoPaulo, Brazil, July 2012.

11. Co-organizer, Minisymposium on Finite element methods and high performance computing forenvironmental fluid mechanics, The 11th US National Congress on Computational Mechanics,Minneapolis, MN, July 2011.

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12. Co-organizer, Minisymposium on Finite element methods and high performance computing forenvironmental fluid mechanics, The 9th World Congress on Computational Mechanics, Sydney,Australia, July 2010.

13. Co-organizer, Minisymposium on Finite element methods and high performance computing forenvironmental fluid mechanics, The 10th US National Congress on Computational Mechanics,Columbus, OH, July 2009.

• Technical Reviewer:

– Journal Review: Advances in Water Resource,Coastal Engineering; Computational Geosciences;Computer Methods in Applied Mechanics and Engineering; Estuarine, Coastal and Shelf Sci-ence; International Journal for Numerical Methods in Fluids; Journal of Engineering Mathemat-ics; Journal of Hydraulic Engineering; Journal of Marine Geodesy; Journal of Waterway, Port,Coastal, and Ocean Engineering; Ocean Dynamics; Ocean Modelling; PLOS ONE.

– Proposal Review:

1. National Science Foundation Review Panel for Division of Mathematical Sciences, March 2013.

2. National Science Foundation Review Panel for Division of Mathematical Sciences, April 2012.

3. National Science Foundation Virtual Review Panel for Division of Mathematical Sciences, April2012.

4. National Science Foundation Review Panel for Division of Mathematical Sciences, March 2010.

5. Ohio Water Resources Center and the National Institutes for Water Resources (NIWR) StateWater Resources Research Institute, December 2009.

6. Army Research Office, December 2009.

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