View metadata, citation and similar papers at core.ac.uk brought to you by CORE provided by DigitalCommons@Florida International University Florida International University FIU Digital Commons Center for Coastal Oceans Research Faculty Institute of Water and Enviornment Publications 3-13-2017 Limits on carbon sequestration in arid blue carbon ecosystems Lisa M. Schile Smithsonian Environmental Research Center Boone Kauffman Oregon State University Stephen Crooks Silverstrum Climate Associates James W. Fourqurean Department of Biological Sciences and Marine Education Research Center, Institute for Water and Environment, Florida International University, [email protected] Jane Glavan Abu Dhabi Global Environmental Data Initiative See next page for additional authors Follow this and additional works at: https://digitalcommons.fiu.edu/merc_fac Part of the Life Sciences Commons Recommended Citation Schile, L. M., Kauffman, J. B., Crooks, S., Fourqurean, J. W., Glavan, J. and Megonigal, J. P. (2017), Limits on carbon sequestration in arid blue carbon ecosystems. Ecol Appl, 27: 859–874. doi:10.1002/eap.1489 This work is brought to you for free and open access by the Institute of Water and Enviornment at FIU Digital Commons. It has been accepted for inclusion in Center for Coastal Oceans Research Faculty Publications by an authorized administrator of FIU Digital Commons. For more information, please contact [email protected]. Authors Lisa M. Schile, Boone Kauffman, Stephen Crooks, James W. Fourqurean, Jane Glavan, and Patrick Megonigal This article is available at FIU Digital Commons: https://digitalcommons.fiu.edu/merc_fac/1 Ecological Applications, 27(3), 2017, pp. 859–874 © 2016 by the Ecological Society of America Limits on carbon sequestration in arid blue carbon ecosystems LISA M. SCHILE,1,6 J. BOONE KAUFFMAN,2 STEPHEN CROOKS,3 JAMES W. FOURQUREAN,4 JANE GLAVAN,5 AND J. PATRICK MEGONIGAL1 1Smithsonian Environmental Research Center, 647 Contees Wharf Road, Edgewater, Maryland 21037 USA 2Department of Fisheries and Wildlife, Oregon State University, 104 Nash Hall, Corvallis, Oregon 97331 USA 3Silvestrum Climate Associates, LLC, 150 Seminary Drive 1E, Mill Valley, California 94941 USA 4Department of Biological Sciences and Marine Education and Research Center, Institute for Water and Environment, Florida International University, 11200 SW 8th Street, Miami, Florida 33199 USA 5Abu Dhabi Global Environmental Data Initiative (AGEDI), PO Box 45553, Abu Dhabi, UAE Abstract. Coastal ecosystems produce and sequester significant amounts of carbon (“blue carbon”), which has been well documented in humid and semi-humid regions of temperate and tropical climates but less so in arid regions where mangroves, marshes, and seagrasses exist near the limit of their tolerance for extreme temperature and salinity. To better understand these unique systems, we measured whole- ecosystem carbon stocks in 58 sites across the United Arab Emirates (UAE) in natural and planted mangroves, salt marshes, seagrass beds, micro- bial mats, and coastal sabkha (inter- and supratidal unvegetated salt flats). Natural mangroves held significantly more carbon in above- and belowground biomass than other vegetated eco- systems. Planted mangrove carbon stocks increased with age, but there were large differences for sites of similar age. Soil carbon varied widely across sites (2–367 Mg C/ha), with ecosystem averages that ranged from 49 to 156 Mg C/ha. For the first time, microbial mats were docu- mented to contain soil carbon pools comparable to vascular plant-dominated ecosystems, and could arguably be recognized as a unique blue carbon ecosystem. Total ecosystem carbon stocks ranged widely from 2 to 515 Mg C/ha (seagrass bed and mangrove, respectively). Seagrass beds had the lowest carbon stock per unit area, but the largest stock per total area due to their large spatial coverage. Compared to similar ecosystems globally, mangroves and marshes in the UAE have lower plant and soil carbon stocks; however, the difference in soil stocks is far larger than with plant stocks. This incongruent difference between stocks is likely due to poor carbon preservation under conditions of weakly reduced soils (200–350 mV), coarse- grained sediments, and active shoreline migration. This work represents the first attempt to produce a country-wide coastal ecosystem carbon accounting using a uniform sampling protocol, and was motivated by specific policy goals identified by the Abu Dhabi Global Environmental Data Initiative. These carbon stock data supported two objectives: to quantify carbon stocks and infer sequestration capacity in arid blue carbon ecosystems, and to explore the potential to incorporate blue carbon science into national reporting and planning documents. Key words: Abu Dhabi; Arthrocnemum macrostachyum; Avicennia marina; blue carbon; carbon pools; carbon stocks; Halodule uninervis; Halophila ovalis; Halophila stipulacea; United Arab Emirates. INTRODUCTION challenges for the application of coastal ecosystem carbon research at local and regional scales. A major lim- Vegetated coastal ecosystems produce and sequester itation is that field research has focused primarily on significant amounts of organic carbon (Chmura et al. study sites located in humid regions at temperate and 2003, Duarte et al. 2005, Donato et al. 2011, McLeod tropical latitudes (Chmura et al. 2003, Donato et al. 2011, et al. 2011, Fourqurean et al. 2012a), generating wor- Adame et al. 2013, Fourqurean et al. 2012a, Kauffman ldwide interest in the management, conservation, and et al. 2014, Alongi et al. 2015), with relatively few studies restoration of mangroves, marshes, and seagrasses for in sub- humid or arid regions (Adame et al. 2013, Ezcurra the purpose of climate change mitigation (McLeod et al. et al. 2016) where differences in rainfall, evapotranspi- 2011, Pendleton et al. 2012). The recent increase in ration, and soil conditions could affect carbon storage. attention to these “blue carbon” ecosystems has exposed The limited range of climates examined makes it difficult considerable gaps in our understanding of carbon pools to assess the potential for carbon-based ecosystem and sequestration rates in coastal environments, creating management across sites that vary tremendously across gradients of coastal climate, hydrology, geomorphology, Manuscript received 30 April 2016; revised 15 November and tide range (Sifleet et al. 2011), and limits our ability 2016; accepted 1 December 2016. Corresponding Editor: Yude Pan. to generalize knowledge outside of warm humid regions. 6E-mail: [email protected] Perhaps the least- studied intertidal marine ecosystems 859 860 LISA M. SCHILE ET AL. Ecological Applications Vol. 27, No. 3 occur in arid regions. Coastlines in the Arabian Gulf low net primary production, and in regions of high and contain a mosaic of productive ecosystems, including low temperature. coastal sabkha (broad, flat inter- and supratidal salt flats lacking vascular plants), mudflats, cyanobacterial mats Study sites (hereafter microbial mats), mangroves, seagrasses and coral reefs, among others, that provide food and habitat We studied coastal and near-shore ecosystems within for diverse ecological communities and support over half the UAE (Fig. 1). Along the Arabian Gulf, air tempera- a billion dollars in fisheries activities annually (Burt tures seasonally range from 12° to >50°C, and water tem- 2014). There is presently a dearth of research in arid tidal peratures at the coastal margins range seasonally from wetland and seagrass (herein blue carbon) ecosystems 10° to 36°C (EAD 2007, Piontkovski et al. 2012). Average even though large investments have been made in cre- annual rainfall is <100 mm and is much less than evapo- ation, restoration and protection activities by nations of ration rates of 1000–2000 mm (Evans et al. 1973). Salinity the Arabian Peninsula (Aoki and Kugaprasatham 2009). in the Arabian Gulf is high due to restricted tidal exchange Although plants in arid systems are adapted to survive and high rates of evaporation, reaching values >70 PSU under these conditions, they exist near the limit of their in lagoons and other shallow waters during summer tolerance for extremes in temperature, rainfall, and (EAD 2007). Localized areas of lower salinity are created salinity. Despite these potential limits (Noy- Meir 1973), by urban water outflows, through drainage networks low primary production does not necessarily prevent (i.e., wadis) from mountain areas to the north and east, long- term accumulation of large soil carbon pools in blue and increased water circulation following channel con- carbon ecosystems, provided that soil carbon is preserved struction and dredging (Embabi 1993). Along the Gulf of by development of anaerobic soil conditions. For Oman, average air temperature is 28°C and rainfall example, mangrove forests that differ widely in plant amounts range from 12 to 331 mm, averaging 138 mm in biomass (e.g., 6.8–194.3 Mg/ha; Lovelock et al. 2005) Khalba (Böer 1997). Tides are complex, driven by inter- nonetheless can form deep (7 m), organic (80% organic fering standing waves across the Arabian Gulf, resulting matter) soil profiles. Furthermore, low primary pro- in a mix of diurnal and semi- diurnal tides, with a spring duction in northern peatlands outweighs very slow range of approximately 2.5 m (see Appendix S1 for decomposition rates over millennia, resulting in extremely further details). carbon rich soils despite that fact that plant production Mangroves within the