Tropical Marine Ecology. Daniel M. Alongi

Tropical Marine Ecology - Daniel M. Alongi


Скачать книгу
act in concert with maximum plume outflow, causing sediments to be dispersed farther from the delta mouth. Sediments can be dispersed over relatively wide areas that extend considerable distances from the delta; some rivers do not have a subaerial delta or do not protrude much beyond the regional coastline. Alongshore dispersal of sediments takes place primarily on the inner shelf but near the delta mouth the depth is too shallow and energetic for fine‐grain sediments to be deposited, except temporarily (Hetland and Hsu 2014). Much of the material transported alongshore becomes sequestered within tidal currents, and off the Amazon, muds that are transported alongshore ultimately accumulate, forming expensive, accumulating mud banks hundreds of km to the NW of the mouth. Despite a high level of instability, these mud banks are colonised by mangroves. However, the Amazon is characterised by accumulations of sediments as subaqueous delta deposits at relatively large distances on the mid‐shelf. A large fraction of Amazon sediments reaches the mid‐shelf due to the energetic currents and waves that sustain sediments in suspension until they reach relatively deep water (Wright and Friedrichs 2006). Much of the observed diversity of sediment dispersal and accumulation is attributable to variations in coastal energy regimes and to the temporal sequencing of river discharge relative to oceanographic transport processes. Sediment transport in the southeast section of the Amazon coastal zone is greatly affected by tidal asymmetry, seasonal variation of the wind and wave regime, and river discharge (Gomes et al. 2020). Climate and geological configuration have resulted in numerous estuaries and large‐mangrove‐lined coastal plains that partially divided the estuarine basins, which are connected by tidal channels within the Amazon delta. Convergence of transported sediment occurs within a channel connecting the estuaries, resulting in mud retention and further delivery to the mangrove‐covered plains, with a net flux of suspended sediments between estuaries. The connectivity between estuaries via channels is a key process to redistribute muddy sediments along this coastal sector, which helps to explain the evolution and maintenance of the relatively homogenous and widespread progradation of mangroves along the coast.

      Mechanisms that dominate the short‐term spreading and mixing of riverine sediment may differ from the mechanisms that determine the longer‐term dispersal of sediment. Sediment records from the South China Sea show that strong monsoons are associated with intensified reworking of pre‐existing floodplain sediment over millennial timescales (Clift 2020). Strong monsoons result in deposition of more altered material that is also delivered at higher rates than during drier periods. Millennial‐scale changes in monsoon strength result in changes in the weathering regime but not fast enough to account for the changes seen in the sediments preserved in Asian deltas; instead, monsoon‐modulated recycling dominates. Over longer time periods (>106 year) strengthening of the monsoon is linked to faster bedrock erosion and increased sediment flux to the ocean.

      An additional complication is the fact that most tropical river systems are heavily affected by humans; few, if any, tropical rivers are pristine. Human disturbances such as the construction of dams and deforestation can greatly impact water and sediment discharge. Increased greenhouse gas emissions are projected to impact twenty‐first century precipitation distribution, altering riverine water and sediment discharge. Modelling indicates that increasing global warming will lead to more extreme changes and greater rates of increasing or decreasing changes in fluvial discharge (Moragoda and Cohen 2020). At the end of the twenty‐first century under all IPCC climate change scenarios, mean global river discharge will increase by 2–11% relative to the 1950–2005 period, while global suspended sediment flux will increase by 11–16% under pristine conditions. Combining the effects of climate change with natural and anthropogenic impacts, tropical rivers have and will continue to be affected greatly in future. For example, natural and human‐induced factors have greatly altered the discharge of the Patía River of Colombia (Restrepo and Kettner 2012). In 1972, the river flow was diverted to an adjacent river resulting in several environmental changes, such as coastal retreat along the abandoned delta, the formation of barrier islands with exposed peat soils in the surf zone, abandonment of former active distributions in the southern delta plain with associated closing of inlets and formation of ebb tidal inlets, breaching events on the barrier islands, and accretion on the northern delta plain.

Schematic illustration of idealised model of the factors and processes contributing to vertical changes within river deltas in the face of rising sea-level.

      Source: Darby et al. (2020), figure 5.1, p. 105. Licensed under CC BY 4.0. © Springer Nature Switzerland AG.


Скачать книгу