Global coastal wetland change under sea-level rise and related stresses: The DIVA Wetland Change Model

• Published in: Global and planetary change Vol. 139; pp. 15 - 30
• Main Authors: Spencer, Thomas, Schuerch, Mark, Nicholls, Robert J., Hinkel, Jochen, Lincke, Daniel, Vafeidis, A.T., Reef, Ruth, McFadden, Loraine, Brown, Sally
• Format: Journal Article
• Language: English
• Published: Elsevier B.V 01.04.2016
• Subjects: Accommodation; Accommodation space; climate; Coastal; coasts; Construction; data collection; Dikes; expert opinion; Marine; Mathematical models; Raw materials; salt marshes; sea level; Sea-level rise; Sediments; Tidal wetlands; Wetland loss; Wetland transitions; Wetland vulnerability; Wetlands; Wetland vulnerability; Accommodation space; Wetland transitions; Wetland loss; Tidal wetlands; Sea-level rise
• ISSN: 0921-8181; 1872-6364
• DOI: 10.1016/j.gloplacha.2015.12.018

The Dynamic Interactive Vulnerability Assessment Wetland Change Model (DIVA_WCM) comprises a dataset of contemporary global coastal wetland stocks (estimated at 756×103km2 (in 2011)), mapped to a one-dimensional global database, and a model of the macro-scale controls on wetland response to sea-level rise. Three key drivers of wetland response to sea-level rise are considered: 1) rate of sea-level rise relative to tidal range; 2) lateral accommodation space; and 3) sediment supply. The model is tuned by expert knowledge, parameterised with quantitative data where possible, and validated against mapping associated with two large-scale mangrove and saltmarsh vulnerability studies. It is applied across 12,148 coastal segments (mean length 85km) to the year 2100. The model provides better-informed macro-scale projections of likely patterns of future coastal wetland losses across a range of sea-level rise scenarios and varying assumptions about the construction of coastal dikes to prevent sea flooding (as dikes limit lateral accommodation space and cause coastal squeeze). With 50cm of sea-level rise by 2100, the model predicts a loss of 46–59% of global coastal wetland stocks. A global coastal wetland loss of 78% is estimated under high sea-level rise (110cm by 2100) accompanied by maximum dike construction. The primary driver for high vulnerability of coastal wetlands to sea-level rise is coastal squeeze, a consequence of long-term coastal protection strategies. Under low sea-level rise (29cm by 2100) losses do not exceed ca. 50% of the total stock, even for the same adverse dike construction assumptions. The model results confirm that the widespread paradigm that wetlands subject to a micro-tidal regime are likely to be more vulnerable to loss than macro-tidal environments. Countering these potential losses will require both climate mitigation (a global response) to minimise sea-level rise and maximisation of accommodation space and sediment supply (a regional response) on low-lying coasts. •Database identifies estimated (in 2011) 756×103km2 global coastal wetland stock.•With 50cm of sea-level rise by 2100, losses of 46–59% of global coastal wetlands•Under high sea-level rise (110cm by 2100), global wetland losses may reach 78%.•Under low sea-level rise, micro-tidal wetlands more vulnerable to loss•Wetland loss likely to be exacerbated by non-climate related, anthropogenic impacts