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245 00 |a Simulated sea level change alters anatomy, physiology, growth, and reproduction of red mangrove (Rhizophora mangle L.) |h [electronic resource].
260        |a [S.l.] : |b Springer-Verlag, |c 1997.
490        |a Oecologia Volume 112.
506        |a Please contact the owning institution for licensing and permissions. It is the user's responsibility to ensure use does not violate any third party rights.
520 3    |a ct Tropical coastal forests ± mangroves ± will be one of the ®rst ecosystems to be a€ected by altered sea levels accompanying global climate change. Responses of mangrove forests to changing sea levels depend on reactions of individual plants, yet such responses have not been addressed experimentally. We report data from a long-term greenhouse study that assessed physiological and individual growth responses of the dominant neo- tropical mangrove, Rhizophora mangle, to levels of inundation expected to occur in the Caribbean within 50± 100 years. In this study, we grew potted plants in tanks with simulated semidiurnal (twice daily) high tides that approximated current conditions (MW plants), a 16-cm increase in sea level (LW plants), and a 16-cm decrease in sea level (HW plants). The experiment lasted 2‰ years, beginning with mangrove seedlings and termi- nating after plants began to reproduce. Environmental (air temperature, relative humidity, photosynthetically active radiation) and edaphic conditions (pH, redox, soil sul®de) approximated ®eld conditions in Belize, the source locale for the seedlings. HW plants were shorter and narrower, and produced fewer branches and leaves, responses correlated with the development of acid- sul®de soils in their pots. LW plants initially grew more rapidly than MW plants. However, the growth of LW plants slowed dramatically once they reached the sapling stage, and by the end of the experiment, MW plants were 10±20% larger in all measured growth parameters. Plants did not exhibit di€erences in allometric growth as a function of inundation. Anatomical characteristics of leaves did not di€er among treatments. Both foliar C:N and root porosity decreased from LW through MW to HW. Relative to LW and HW plants, MW plants had 1±7% fewer stomata/mm2, 6±21% greater maximum photosynthetic rates, 3±23% greater absolute relative growth rates (RGRs), and a 30% higher RGR for a given increase in net assimilation rate. Reduced growth of R. mangle under realistic conditions approximating future inundation depths likely will temper projected increased growth of this species under concomitant increases in the atmospheric concentration of CO2
533        |a Electronic reproduction. |c Florida International University, |d 2015. |f (dpSobek) |n Mode of access: World Wide Web. |n System requirements: Internet connectivity; Web browser software.
650    0 |a Climate Change.
650    0 |a Sea Level Rise.
650    0 |a Red mangrove.
650    0 |a Photosynthesis.
720 1    |a Ellison, Aaron M..
720 1    |a Farnsworth, Elizabeth J..
773 0    |t Simulated sea level change alters anatomy, physiology, growth, and reproduction of red mangrove (Rhizophora mangle L.)
830    0 |a dpSobek.
830    0 |a Sea Level Rise.
852        |a dpSobek |c Sea Level Rise
856 40 |u http://dpanther.fiu.edu/dpService/dpPurlService/purl/FI15061985/00001 |y Click here for full text
856 42 |3 Host material |u http://link.springer.com/article/10.1007%2Fs004420050330 |y Simulated sea level change alters anatomy, physiology, growth, and reproduction of red mangrove (Rhizophora mangle L.)
992 04 |a http://dpanther.fiu.edu/sobek/content/FI/15/06/19/85/00001/FI15061985thm.jpg
997        |a Sea Level Rise


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