S1518 Coastal Wetlands, Lagoons and Estuaries: Environmental Monitoring and Management (Sustainable Development Sp. Track)

Silvestri Sonia

What are the main environmental issues in coastal lagoons and estuaries? What are the chief physical processes driving them? Why should we maintain coastal wetlands? Lagoons, deltas and estuaries are subject to rapid and sometimes extreme changes, in response to natural and anthropogenic pressures. Importantly, the responses are not just related to physical processes, such as sediment dynamics induced by hydrodynamic patterns or extreme meteorological events, but also to ecological dynamics, in connection with vegetation cover, and the biological status of the sediments. Beside their evident ecological importance, coastal humid areas are often the location of important human settlements and the centre of relevant social/cultural interests. In fact, direct or indirect human interference has produced in the past - and is still producing - rapid morphological and ecological modifications of estuaries and lagoons worldwide. Venice and its lagoon are a well-documented and representative example of the possible outcomes of human-natural systems interactions in coastal environments.
The course is designed for both a technical and non-technical audience in that it addresses general environmental issues in lagoons, estuaries/deltas and wetlands. The main processes driving change in these environments will be presented, as well as the dominant eco-morphological processes, in terms of how they respond to pressures like changing sea levels and water quality issues related to sustaining marshes and aquaculture. The course will use the history of the Venice lagoon, as well as descriptions of its more recent modifications, as an illustration of the issues connected with changes in coastal lagoons and estuaries driven by human impacts, induced climatic changes, and natural environmental dynamics. Adaptation measures to rising sea levels will be discussed, with particular reference to the MOSE system, the system of barriers currently being constructed to protect the city of Venice from extreme high tides.
The course will also focus on observing, monitoring, and environmental assessment: the necessary basis for management policies. Wetland functions, hydrology, decomposition, community habitat, and productivity will be discussed in an ecosystem context. Against this background the use of constructed wetlands for wastewater treatment and erosion control will also be presented. Students will acquire familiarity with various monitoring technologies, with particular interest for satellite remote-sensing tools (this part will be synergistic with the course “Introduction to satellite remote sensing of coastal environments”). Applications to the Venice Lagoon will also be discussed in detail through hands-on projects.

Course objectives and outcomes
- To develop (1) an understanding of the main natural and anthropogenic drivers of the evolution of environments subjected to tidal forcings, including both biotic and abiotic components; (2) a conceptual understanding of wetland preservation and restoration concepts and related topics; (3) the ability to analyze resource and management problems in coastal restoration.
- To analyze (1) wetland functions, ecosystem services and management strategies for wetland and coastal restoration; (2) specific examples of protection/restoration activities applied in the Venice Lagoon.
- To develop (1) an understanding of how in-situ and remote sensing observations can support our understanding of coastal ecological and morphological dynamics.
- To provide students with (1) the opportunity for reviewing and discussing restoration procedures and restoration assessments; (2) experience in leading a seminar and critiquing research papers.

Several modes of teaching are utilized: lectures, readings (readings in research articles are critiqued and students are asked to prepare a written analysis of articles), digital data analysis in the computer lab. Three field trips in the Venice Lagoon by boat will be utilized, to visit restored salt marshes, barrier islands protection structures and the MOSE system.

Course duration and organization
The global course duration is 13 weeks + 1 week for the exams.
In general there are 2 lessons/labs per week (90 minutes each), for a total of 3 hrs per week.
5 lessons will be taught from remote (from Duke University) while all the other lessons and labs will be hold in Venice.
Total lecture hours: 24 hours
Total computer lab sessions: 12 hours
Total field trip duration: 18 hours.

Resources
A computer lab with 20 work stations or PCs fully equipped with software for GIS data analysis, plus the assistance of Dr. Ludovica Galeazzo for lab sessions. One projector. Fast Internet connection for remote teaching.

Field Trips:

The 3 field trips are mandatory and will be organized on the following dates:
March 13 Field trip to the Venice lagoon salt marshes
March 20 Field trip to Murazzi
May 15 Field trip to MOSE

Syllabus

The global course duration is 13 weeks + 1 week for the exams:
April 6nd – April 10th: spring break

February 2015
Mon 23 Lecture Coastal system morphology – in Venice
Introduction to coastal environments: definitions and main controlling processes.
Wed 25 Lecture Coastal system morphology – in Venice
Coastal lagoons, estuaries and deltas: definitions and characteristics. Typical morphological structures and ecological properties of tidal environments. Geomorphological classifications.

March 2015
Mon 2 Lecture Shaping forces of the coastal morphology – in Venice
Tides, storm surges, water circulation, and waves.
Wed 4 Lecture Ecogeomorphology – in Venice
Biotic and abiotic processes shaping the tidal landscape. Biomorphodynamics. The role of salt marsh vegetation in trapping and stabilizing sediments. The role of phanerogams (seagrass) in retaining and stabilizing the bottom.
Mon 9 Lecture The Venice lagoon as a natural lab – in Venice
History of the evolution of the Venice Lagoon. Environmental issues faced by Venice in history and the adopted management solutions. Venice as an example of current typical issues of coastal lagoons: depositional/erosional trends, water quality degradation, sea level rise and exceptional high tides.
Wed 11 Lecture The Venice lagoon as a natural lab – in Venice
Natural and restored salt marshes in the Venice lagoon.
Fri 13 Field trip to the Venice lagoon salt marshes
Visit to natural and restored salt marshes.
Mon 16 Lecture Monitoring and management – in Venice
The importance of the geospatial analysis for monitoring and managing a coastal environment. What is a Geographic Information System? Remote sensing and other monitoring methods applied to the Venice lagoon.
Wed 18 Lab #1 - 2hrs (joint with the course “Cities, Global Change and Sustainable Development ”) – in Venice
delivered by Ludovica Galeazzo : Introduction to GIS systems
Fri 20 Field trip to Murazzi
Visit to Murazzi and to the museum of Pellestrina.
Mon 23 Lab #2 - 2hrs (joint with the course “Cities, Global Change and Sustainable Development ”) – in Venice
delivered by Ludovica Galeazzo: Introduction to GIS systems
Wed 25 Lecture Wetlands – remotely from Durham
Wetlands: characteristics and definitions. Wetland functions and ecosystem services. Biogeochemical cycles in wetlands.
Assignment of the midterm test (due right after the spring break)
Mon 30 NO CLASS

April 2015
Wed 1 Lab #3 - 2hrs (joint with the course “Cities, Global Change and Sustainable Development ”) – in Venice
delivered by Ludovica Galeazzo : Introduction to GIS systems

April 6 – April 10: spring break

Mon 13 Lecture Coastal wetlands – remotely from Durham
midterm test due
Wetlands and greenhouse gasses. Peatland: the example of the Zennare basin (southern part of the Venice lagoon watershed).

Wed 15 Lab #4 - 2hrs (joint with the course “Cities, Global Change and Sustainable Development ”) – in Venice
delivered by Ludovica Galeazzo: Introduction to GIS systems
(Fri 17 Field trip to Arsenale)
Not mandatory
Mon 20 Lab #5 - 2hrs (joint with the course “Cities, Global Change and Sustainable Development ”) – in Venice
delivered by Ludovica Galeazzo: Introduction to GIS systems
Wed 22 Lecture Coastal wetlands – remotely from Durham
Wetland functions and services with examples from around the world. The role of ecology in the formation and development of wetlands and of coastal marshes. The value of wetlands. Constructed wetlands. Wetland restoration principles and case studies. Constructed wetlands and water quality.
Mon 27 Lecture Coastal wetlands – remotely from Durham
Monitoring the long-term success of restored wetlands. The ecology of wetlands, marshes and coastal areas: plants and organisms and their physiological adaptations to coastal environments.
Wed 29 Lecture Water quality – remotely from Durham
Water quality monitoring options and techniques. Remote sensing of water quality. A comparison of historical changes in quality over time due to anthropogenic activities. Remote sensing applied to the observation of climate change phenomena and measurements.

May 2015
Mon 4 Lab #6 - 2hrs (joint with the course “Cities, Global Change and Sustainable Development ”) – in Venice
delivered by Ludovica Galeazzo: Introduction to GIS systems
Wed 6 NO CLASS
Mon 11 Lecture Putting all together – in Venice
Take home messages on the state and processes in coastal areas
Wed 13 Lecture Climate and climate change – in Venice
Causes and consequences of climate change

Fri 15 Field trip to MOSE
Guest speaker: Elena Zambardi – Consorzio Venezia Nuova.
Mon 18 Lecture Climate change and sea level rise – in Venice
Causes and consequences of sea level rise on coastal areas
Wed 20 Lecture Climate change and sea level rise – in Venice
Monitoring climate change and sea level rise
Mon 25 Final presentations – in Venice
Wed 27 Final presentations – in Venice

Evaluation
Readings

Examples of readings (texts, primary literature, popular press, etc.):
Canada Centre for Remote Sensing Fundamentals of Remote Sensing, http://www.nrcan.gc.ca/earth-sciences/geography-boundary/remote-sensing/fundamentals/1430
M. Mitsch, W.J. and J.G. Gosselink. 2007. Wetlands, New York: John Wiley, 2007, 4th edition.

Sample papers:

Barbier, E.B., Hacker, S.D., Kennedy, C., Koch, E.W., Stier, A.C., Silliman, B.R., 2011. The value of estuarine and coastal ecosystem services. Ecol Monogr 81, 169-193. Required reading + critique assignment
Belluco et al. 2006, Mapping salt-marsh vegetation by multispectral and hyperspectral remote sensing, Remote Sensing of Environment, 105, 54–67.
Bertness, M.D. and A.M. Ellison. 1987. Determinants of pattern in a New England salt marsh plant community. Ecological Monographs 57:129-147.
K. Bromberg Gedan, B.R. Silliman, and M.D. Bertness (2009) Centuries of Human-Driven Change in Salt Marsh Ecosystems, Annual Review of Marine Science. Vol. 1: 117-141. DOI: 10.1146/annurev.marine.010908.163930
L. Carbognin, P. Teatini, L. Tosi (2004) Eustacy and land subsidence in the Venice Lagoon at the beginning of the new millennium. Journal of Marine Systems Volume 51, Issues 1–4, Pages 345–353.
Carniello, L., A. Defina, and L. D'Alpaos (2009), Morphological evolution of the Venice lagoon: Evidence from the past and trend for the future, J. Geophys. Res., 114, F04002, doi:10.1029/2008JF001157.
Carr, J. A., P. D’Odorico, K. J. McGlathery, and P. L. Wiberg (2012), Stability and resilience of seagrass meadows to seasonal and interannual dynamics and environmental stress, J. Geophys. Res., 117, G01007, doi:10.1029/2011JG001744.
Chander G., Markham B.L., Helder D.L. (2009), Summary of current radiometric calibration coefficients for Landsat MSS, TM, ETM+ and EO-1 ALI sensors. Remote Sensing of Environment, 113, 893-903.
Chmura G.L., Anisfeld S.C., Cahoon D.R. and Lynch J.C. (2003). Global carbon sequestration in tidal, saline wetland soils. Global Biogeochemical Cycles, 17(4), 1111, doi: 10.1029/2002GB001917, pp: 1 –12. Required reading
Craft, C., Clough, J., Ehman, J., Joye, S., Park, R., Pennings, S., Guo, H.Y., Machmuller, M., 2009.Forecasting the effects of accelerated sea-level rise on tidal marsh ecosystem services.Front Ecol Environ 7, 73-78.
Feagin, R.A., Martinez, M.L., Mendoza Gonzalez, G., Costanza, R., 2010. Salt marsh zonal migration and ecosystem service change in response to global sea level rise: a case study from an urban region. Ecol Soc 15.
Gedan, K.B., Kirwan, M.L., Wolanski, E., Barbier, E.B., Silliman, B.R., 2011. The present and future role of coastal wetland vegetation in protecting shorelines: answering recent challenges to the paradigm. Climatic Change 106, 7-29. Required reading + critique assignment

Gedan, K.B., Silliman, B.R., Bertness, M.D., 2009. Centuries of human-driven change in salt marsh ecosystems. Annul Rev Mar Sci. 1, 117-141.
Giblin, A.E., Weston, N.B., Banta, G.T., Tucker, J., Hopkinson, C.S., 2010. The effects of salinity on nitrogen losses from an oligohaline estuarine sediment. Estuaries and Coasts 33, 1054‐1068.
Gledhill, D. K., R. Wanninkhof, and C. M. Eakin. 2009. Observing ocean acidification from space. Oceanography 22: 48-59.
Howarth, R.W. and Teal, J.M. 1979. Sulfate reduction in a New England salt marsh. Limnology and Oceanography 24:999-1013.
IPCC Fifth Assessment Report 2013. Climate Change 2013: Chapter 13: Sea Level Change. 121p. Required reading (Students will be asked to read 20 to 30 pages extracted from the report)
Kirwan, M.L., Guntenspergen, G.R. Morris, J.T. 2009. Latitudinal trends in Spartina alterniflora productivity and the response of coastal marshes to global change. Glob. Change Biol. 15,1982‐1989.
Kirwan, M.L., Guntenspergen, G.R., D'Alpaos, A., Morris, J.T., Mudd, S.M., Temmerman, S., 2010. Limits on the adaptability of coastal marshes to rising sea level. Geophys Res Lett 37. Required reading + critique assignment
Marani, M., A. D'Alpaos, S. Lanzoni, L. Carniello, A. Rinaldo, The importance of being coupled: Stable states, catastrophic shifts and hysteresis in tidal eco-morphodynamics, Journal of Geophysical Research, vol. 115, F04004, doi:10.1029/2009JF001600, 2010.
M. Marani, S. Silvestri, E. Belluco, N. Ursino, A. Comerlati, O. Tosatto, M. Putti, Spatial organization and ecohydrological interactions in oxygen-limited vegetation ecosystems, Water Resour. Res., 42, W06D06, doi:10.1029/2005WR004582, 2006.
Marani, M., S. Lanzoni, S. Silvestri, and A. Rinaldo, Tidal landforms, patterns of halophytic vegetation and the fate of the lagoon of Venice, J. Marine Syst., vol.51, 191-210, 2004.
Mendelssohn, I.A. K.L. McKee, and W.H. Patrick, Jr. 1981. Oxygen deficiency in Spartina alterniflora roots: metabolic adaptation to anoxia. Science 214:439-441.
Morris, J.T., Sundareshwar, P.V., Nietch, C.T., Kjerfve, B., Cahoon, D.R., 2002. Responses of coastal wetlands to rising sea level. Ecology 83, 2869-2877.
Neubauer, S.C., 2011. Ecosystem responses of a tidal freshwater marsh experiencing saltwater intrusion and altered hydrology. Estuaries and Coasts.
Nixon, S.W. 1980. Between coastal marshes and coastal waters - a review of twenty years of speculation and research on the role of salt marshes in estuarine productivity and water chemistry. pp. 437-525 in: Hamilton, P. and K.B. Macdonald (eds.) Estuarine and wetlands processes with emphasis on modeling. New York: Plenum Press.Teal, J.M. 1962. Energy flow in the salt marsh ecosystem of Georgia. Ecology 43:614-624.
Pandolfi, J. M., S. R. Connolly, D. J. Marshall, and A. L. Cohen. 2011. Projecting coral reef futures under global warming and ocean acidification. Science 333: 418‐422.
Rahmstorf, S. 2007. A semi-empirical approach to projecting future sea-level rise. Science 315, 368‐370.
Redfield, A.C. 1972. Development of a New England salt marsh. Ecological Monographs 42:201-237.
Silvestri S., Defina A., Marani M., 2005. Tidal regime, salinity and salt marsh plant zonation. Estuarine, Coastal and Shelf Science 62, 119-130.
Spalding, E.A., Hester, M.W., 2007. Interactive effects of hydrology and salinity on oligohaline plant species productivity: Implications of relative sea-level rise. Estuaries and Coasts 30, 214-225.
Troccoli, A., F. Zambon, K.I. Hodges, M. Marani. Storm surge frequency reduction in Venice under climate change. Climatic Change, DOI: 10.1007/s10584-011-0093-x, 2011.
Ursino N., Silvestri S., Marani M., 2004. Subsurface flow and vegetation patterns in tidal environments. Water Resources Research, 40, W05115, doi: 10.1029/2003WR002702
Valiela and Teal. 1979. The nitrogen budget of salt marsh ecosystem. Nature 280:652-656.
Vermeer, M., Rahmstorf, S., 2009. Global sea level linked to global temperature. P Natl Acad Sci USA 106, 21527-21532.
Veron, J. E. N., O. Hoegh-Guldberg, T. M. Lenton, J. M. Lough, D. O. Obura, P. Pearce‐Kelly, C. R. C. Sheppard, M. Spalding, M. G. Stafford-Smith, and A. D. Rogers. 2009. The coral reef crisis: The critical importance of Volpe et al., 2011, Remote sensing retrieval of suspended sediment concentration in shallow waters, Remote Sensing of Environment 115 (2011) 44-54.
Weston, N.B., Porubsky, W.P., Samarkin, V.A., Erickson, M., Macavoy, S.E., Joye, S.B., 2006.Porewater stoichiometry of terminal metabolic products, sulfate, and dissolved organic carbon and nitrogen in estuarine intertidal creek‐bank sediments. Biogeochemistry 77, 375-408.
Weston, N.B., Vile, M.A., Neubauer, S.C., Velinsky, D.J., 2011. Accelerated microbial organic matter mineralization following salt-water intrusion into tidal freshwater marsh soils. Biogeochemistry 102, 135-151.

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S1518 Coastal Wetlands, Lagoons and Estuaries: Environmental Monitoring and Management (Sustainable Development Sp. Track)

Silvestri Sonia

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