Spatial displacement of nearshore vegetation in response to artificial changes in coastal morphology Martina Cutajar University of Malta, Malta Sandro Lanfranco University of Malta, Malta This is a section of Ninth International Symposium “Monitoring of Mediterranean Coastal Areas: Problems and Measurement Techniques”(DOI: 10.36253/979-12-215-0030-1) by Laura Bonora, Donatella Carboni, Matteo De Vincenzi, Giorgio Matteucci Firenze University Press Firenze 2022 https://doi.org/10.36253/979-12-215-0030-1.59

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This study characterizes the zonation of coastal vegetation in six coastal sites in Malta. The vegetation sequence on the coastal zone is predictable and displaces in response to changes in shoreline. The halophyte Limbarda crithmoides was used as an indicator species to ‘locate’ the position of the sequence. The vegetation surveys were used to construct a Gaussian distribution model for this species. Peak density and peak distance from the shore were positively correlated with exposure. The models were used to simulate the predicted shift of the vegetation in response to a modified shoreline

 Limbarda crithmoides Coastal vegetation Maltese Islands Land reclamation

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References AgiSoft PhotoScan Professional (Version 1.3.6) (Software). (2020). Retrieved from http://www.agisoft.com/downloads/installer/ Al Hassan, M., Estrelles, E., Soriano, P., López-Gresa, M. P., Bellés, J. M., Boscaiu, M., & Vicente, O. (2017). Unravelling salt tolerance mechanisms in halophytes: a comparative study on four Mediterranean Limonium species with different geographic distribution patterns. Frontiers in plant science, 8, 1438. 10.3389/fpls.2017.01438 Ávila‐Lovera, E., Garcillán, P. P., Silva‐Bejarano, C., & Santiago, L. S. (2020). Functional traits of leaves and photosynthetic stems of species from a sarcocaulescent scrub in the southern Baja California Peninsula. American Journal of Botany, 107(10), 1410-1422. 10.1002/ajb2.1546 Brullo, S., Brullo, C., Cambria, S., & del Galdo, G. G. (2020). The vegetation of the Maltese Islands. Springer. El-Sheikh, M. A., Al-Sodany, Y. M., Eid, E. M., & Shaltout, K. H. (2012). Ten years primary succession on a newly created landfill at a lagoon of the Mediterranean Sea (Lake Burullus RAMSAR site). Flora-Morphology, Distribution, Functional Ecology of Plants, 207(6), 459-468. 10.1016/j.flora.2012.03.009 Grigore, M. N., Toma, C., Zamfirache, M. M., Ivănescu, L., & Daraban, I. (2013). Anatomical and ecological observations in succulent (articulated) halophytes from Chenopodiaceae. Lucrări Științifice, Universitatea de Științe Agricole Și Medicină Veterinară" Ion Ionescu de la Brad" Iași, Seria Horticultură, 56(2), 19-24. Hardie, M., & Doyle, R. (2012). Measuring soil salinity. In Clifton, N. J., (2012) Methods in molecular biology 415-425. 10.1007/978-1-61779-986-0_28 Khan M.A., & Gul B. (2002) A. macrostachyum : a potential case for agriculture using above seawater salinity. In: Ahmad R., Malik K.A. (eds) Prospects for Saline Agriculture. Tasks for vegetation science, vol 37. Springer, Dordrecht. 10.1007/978-94-017-0067-2_37 Navionics ChartViewer. (2021). Webapp.navionics.com. https://webapp.navionics.com/#boating. Schindelin, J., Arganda-Carreras, I., Frise, E., Kaynig, V., Longair, M., Pietzsch, T., … Cardona, A. (2012). Fiji: an open-source platform for biological-image analysis. Nature Methods, 9(7), 676–682. 10.1038/nmeth.2019 Thomas, M.L.H. (1986) A physically derived exposure index for marine shorelines. Ophelia 25 (1): 1-13. VC Technology LTD. (2021). Litchi™ flight planner application. https://flylitchi.com/hub