Regular ArticleThe Effect of Mangrove Leaf Litter Enrichment on Macrobenthic Colonization of Defaunated Sandy Substrates
References (33)
- et al.
Epibenthos of mangrove waterways and open embayments: community structure and the relationship between exported mangrove detritus and epifaunal standing stocks
Estuarine, Coastal and Shelf Science
(1990) The importance of Sesarminae crabs (Chiromanthes spp.) in mangrove and inundation frequency on the decomposition of mangrove (Kandelia candel (L.) Druce) leaf litter in a Hong Kong tidal shrip pond
Journal of Experimental Marine Biology and Ecology
(1989)The status of three ecosystem-level hypotheses regarding salt marsh estuaries: tidal subsidy, outwelling and detritus-based food chains
Decomposition of mangrove leaf litter in tropical Australia
Journal of Experimental Marine Biology and Ecology
(1988)Hydrodynamic enhancement of invertebrate larval settlement in microdepositional environments: colonization tray experiments in a muddy habitat
Journal of Experimental Marine Biology and Ecology
(1994)Chemical Analysis of Ecological Materials
(1989)The influence of mangrove derived tannins on intertidal meiobenthos in tropical estuaries
Oecologia
(1987)Abundance of benthic microfauna in relation to outwelling of mangrove detritus in a tropical coastals region
Marine Ecology Progress Series
(1990)- et al.
Effect of exported mangrove litter on bacterial productivity and dissolved organic carbon fluxes in adjacent tropical nearshore sediments
Marine Ecology Progress Series
(1989) - et al.
Benthic communities
Influence of mangrove detritus in an estuarine ecosystem
Bulletin of Marine Science
Effects of tidally mediated litter moisture content on decomposition of Spartina alterniflora and S. patens
Marine Biology
Detrital pathways in a coral reef lagoon II. Detritus deposition, benthic microbial biomass and production
Marine Biology
The production of organic detritus in a south Florida estuary
University of Miami Sea Grant Technical Bulletin
Mangrove outwelling: a review
Hydrobiologia
Potential trophic importance of the faecal material of the mangrove sesarmine crab Sesarma messa
Marine Ecology Progress Series
Cited by (62)
Effects of Spartina alterniflora invasion on macrobenthic faunal community in different habitats of a mangrove wetland in Zhanjiang, South China
2023, Regional Studies in Marine ScienceSeagrass beds store less carbon but support more macrobenthos than mangrove forests
2020, Marine Environmental ResearchCitation Excerpt :Compared with MG, sediments in SG are sandier (Table 2). Due to its high content of polyphenols and tannins, difficulty in degradation, and low pH value, the organic matter produced by the litters in mangrove restricted the food sources of macrobenthos and restricted their growth rate (Ellis et al., 2004; Lee, 1999). There are many species of algae in SG (Fredriksen et al., 2005), and SG provide more food choices for macrobenthos.
Changes in carbon storage and macrobenthic communities in a mangrove-seagrass ecosystem after the invasion of smooth cordgrass in southern China
2020, Marine Pollution BulletinCitation Excerpt :Chen and Ma (2018) also found that plant density was the main environmental variable that determined the proportion of functional feeding groups of macrobenthos. The differences in macrobenthic communities between MG and SG have been attributed to the high sulfide concentration and low oxygen in MG sediment (Lee, 1999), which may restrict the entry of macrobenthos. The seagrass canopy can also reduce the velocity of water flow, sediment erosion, and interference of buffers such as water, and help prevent animals from being washed away (Do et al., 2013; Madsen et al., 2001).
Eco-exergy based self-organization of the macrobenthic faunal assemblage during mangrove succession in Zhanjiang, China
2018, Ecological IndicatorsCitation Excerpt :As mangrove succession moves from an unvegetated shoal to a mature mangrove forest, macrobenthic fauna experience a decline in food supply, increased difficulty in burrowing, and increased predation due to the changes in vegetation characteristics and sediment physicochemical properties (Kristensen and Kostka, 2005; Lugendo et al., 2007; Nagelkerken et al., 2008; Hendrarto and Nitisuparjo, 2011). Furthermore, the organic matter generated by mangrove litter accumulates in the late-successional stage and may reduce macrobenthic faunal biomass and richness because of its high polyphenolic and tannin contents as well as its high C/N ratio (Lee, 1999; Chen et al., 2015). Finally, the eco-exergy based self-organization of macrobenthic faunal community obviously differed in the EA site compared with the sites that represented mangrove succession.