Dr. Brian Dzwonkowski
Senior Marine Scientist I
Assistant Professor, University of South Alabama
Brian Dzwonkowski is an Assisstant Professor in the Department of Marine Sciences at the University of South Alabama where he has been a faculty member since 2014. Brian completed his Ph.D. at the University of Delaware and his undergraduate studies at The College of New Jersey. His research interests lie in coastal physical oceanography (things related to the structure and flow of water, i.e. currents, tides, stratification) as well as how physical processes impact biogeochemical cycling and ecosytem function. Brian is also an instructor for a graduate and undergraduate physical oceanography courses at DISL/USA.
2009 Ph.D., Marine Studies w/ concentration in Physical Oceanography, University of Delaware
2003 M.S., Marine Studies w/ concentration in Oceanographic Remote Sensing, University of Delaware
1999 B.A., Mathematics (with NJ teaching certification), The College of New Jersey
In the News:
Dzwonkowski et al. (2015), GoMRI - 06/14/2016 (http://gulfresearchinitiative.org/study-observes-mobile-bay-plume-dynamics-coastal-circulation/).
Dzwonkowski et al. (2017), ACER consortium - 6/19/2017 (http://acer.disl.org/news/2017/06/19/acer-concorde-collaboration-results-in-new-publication/)
I am interested in physical processes that influence three-dimensional transport in the coastal ocean as well as how this transport impacts marine ecosystems.
Circulation and transport processes on coastal shelves and in estuaries provide a pathway for mass property and material exchange, which can have a critical impact on the state of a marine system. This is a challenging (but very interesting) region to study as a result of there being a broad scope of interacting forcing functions that operate on a wide range of temporal and spatial scales in conjunction with an irregular physical environment (i.e. bathymetry and coastal geography). This results in complex flow fields. As such, my research has focused on improving the understanding of the flow field and its associated response to forcing functions at a range of temporal and spatial scales.
By examining estuarine and coastal circulation, I hope to provide a more complete understanding of the processes that dictate the origin, fate, and residence time of material in the coastal ocean. Another aspect of my research involves linking these physical processes to biological aspects of marine system ecosystems. As systems becoming more strongly influenced by anthropogenic impacts, identifying and understanding environmental controls over marine life cycles is essential to elucidating the inter-annual variability that characterizes biological systems.
Through my research efforts, I have also developed a keen awareness of the need to acquire high resolution data on estuarine and coastal physical processes due to the importance of these regions’ ecosystems and their relatively sensitive nature. As such, coastal ocean observing systems provide a critical tool in the efforts of understanding the variability in these systems by providing unprecedented temporal and spatial views of coastal currents and hydrographic conditions.
The continued maintenance and expansion of these observing systems require both operational and scientific justification. Thus, my research focuses on demonstrating new science based on the data provided from these observing systems.
- Expansion of MyMobileBay.com
- DISL Coastal Ocean Observation systems
- NASA SUSMAP: SMAP observations to trace the lifecycle of hydrologic extreme events
- GoMRI Consortium for oil spill exposure pathways in Coastal River-Dominated Ecosystems (CONCORDE)
- Mississippi Water Resources Research Institute
- Center for Environmental Resiliency
- MBNEP Fowl River Marsh Study
I. M. Soto, Cambazoglu, M.K., Boyette, A.D., Broussard, K., Sheehan, D., Howden, S.D., Shiller, A.M., Dzwonkowski, B., Hode, L., Fitzpatrick, P.J., Arnone, R.A., Mickle, P.F., Cressman, K.. Advection of Karenia brevis blooms from the Florida Panhandle towards Mississippi coastal waters Harmful Algae 72, 46–64.
Cambazoglu, M.K., I.M. Soto, S.D. Howden, B. Dzwonkowski, P.J. Fitzpatrick, Y. Lau, R.A. Arnone, and G.A. Jacobs . Inflow of shelf waters into Mississippi Sound and Mobile Bay estuaries in October 2015. Journal of Applied Remote Sensing. 11(3), 032410 doi:10.117/1.JRS.11.032410.
Dzwonkowski, B., A. Greer, C. Briseno-Aveno, J. Krause, I. Soto Ramos, F. Hernandez, A. Deary, J. Wiggert, D. Joung, P. Fizpatrick, S. O’Brien*, S. Dykstra*, Y. Lau, M. Cambazoglu, G. Lockridge*, S. Howden, A. Shiller, and W.M. Graham. Estuarine influence on biogeochemical properties of the Alabama shelf during the Fall season. Continental Shelf Research. 140(15), 96-109.
Tzeng, M. W., B. Dzwonkowski, and K. Park. Data Processing for a Small-Scale Long-Term Coastal Ocean Observing System Near Mobile Bay, Alabama. Earth and Space Science. doi: 10.1002/2016EA000188
Lockridge, G., B. Dzwonkowski, R. Nelson*, and S. Powers. Development of a low-cost Arduino-based sonde for coastal applications. Sensors, 16, 528.
Dzwonkowski, B., K.-C. Wong, and W.J. Ullman. Sea level and velocity characteristics of a salt marsh tidal channel of the Murderkill Estuary, Delaware,
Dzwonkowski, B., K. Park, Lee, J., B. Webb, and A. Valle-Levinson,. Spatial variability in the spring velocity structure on a river -influenced inner shelf in coastal Alabama,
Lee, J., B.M. Webb, B. Dzwonkowski, K. Park, and A. Valle-Levinson. Bathymetric influences on tidal currents at the entrance to a highly stratified, shallow estuary.
Dzwonkowski, B., B.L. Lipphardt, J.T. Kohut, X.-H. Yan, and R.W. Garvine. Synoptic measurements of episodic flow events in the central Mid -Atlantic Bight,
Dzwonkowski, B. and K. Park. Influence of wind stress and discharge on the mean and seasonal currents on the Alabama shelf of the northeastern Gulf of Mexico.
Dzwonkowski B., J.T. Kohut, and X.H. Yan. Seasonal differences in wind -driven across -shelf forcing and response relationships in the shelf surface layer of the central Mid -Atlantic Bight,
Dzwonkowski B., J.T. Kohut, and X.H. Yan. Sub -inertial surface flow field over the shelf of the central Mid -Atlantic Bight,
Wong, K.-C., B. Dzwonkowski, and W.J. Ullman. Temporal and spatial variability of sea level and volume flux in the Murderkill estuary,
Dzwonkowski, B., and X.-H. Yan. Development and application of a neural network based ocean color algorithm in coastal waters,
Dzwonkowski, B., and X.-H. Yan. Tracking of a Chesapeake Bay estuarine outflow plume with satellite -based ocean color data,
Jo, Y.-H., X.-H. Yan, B. Dzwonkowski, and T.W. Liu. A study of the freshwater discharge from the Amazon River into the tropical Atlantic using multi -senor data,
Who We Are
Jeff Coogan, Ph.D. student
Jeff's research interest are focused on estuarine circulation and dynamics. The complex interactions of tides, river discharge, and wind can make predicting salinity changes, currents and physical interactions in estuaries difficult. Theoretical approaches are continually being refined in light of new data based on how to best simplify, parameterize, and understand estuarine physical dynamics. Stratification and mixing are also important characteristic of the flow structure in Mobile Bay and he is examining methods to better understand how this stratification modifies exchange flow. This work has important implications for understanding the relative importance of physical forcing conditions on dissolved oxygen dynamics, which often contributes to hypoxic conditions (i.e. poor water quality).
Steve Dykstra, Ph.D. student
Steve's research interests focus on estuarine and coastal processes that link fluvial and marine environments. Coastal regions with fresh water sources are complex environments due to the large density gradients and tidal-morphology relationships, that together lead to estuarine-terrestrial material transport and high ecological productivity. He is particularly interested in better understanding the impacts of river discharge on a range of physical processes including tidal propagation in estuaries, estuarine-shelf exchange, and river plume dynamics. The interaction between river discharge and these physically processes are critical to improving the understanding the coupled relationship between hydrodynamics and the associated geomorphology of a system.
Graduate Student Committees
Stacy Knapp, University of Maine (Member of thesis committee as of Oct 2012)
Carolyn Garrity, University of Maine (Undergraduate capstone project, 2013)
Lu Han, University of Maine (Undergraduate independent study, Fall 2013)
Nathan Laspina, University of Maine (Undergraduate intern, Summer 2013)
Brett Stacy, Humboldt University (NSF REU, Summer 2012 at DISL)
Amanda Taylor, Coastal Carolina University (NSF REU, Summer 2010 at DISL)