Seagrasses are marine flowering plant that comprises more than 60 different species. It grows by rhizome extension forming like grassland. Seagrasses also photosynthesize in submerged photic zone that mostly occur in shallow coastal water. In productive ecosystem seagrasses beds are diverse that can accommodate hundreds of associated species like fishes, macroalgae, mollusks and nematodes. However, biomass-density relationship becomes the center of research that describes the health of seagrass meadows. Concurrently, biomass-density upper boundaries determined the maximum efficiency of space occupation. In which each distance reflects effective competence in packing biomass which proved as reliable ecological indicators.
Biomass-Density of Seagrasses
The researchers gathered 32 studies on 10 seagrasses species distributed worldwide reveals that seagrasses are limited by boundary line. Upon using the applied metric system on this particular research each stand of seagrass distance are perpendicular to the boundary. However, seagrasses shows poor occupier of space compared to terrestrial plants and algae wherein less volume exploited per unit stand surface. Due to some reasons such as short shoot heights, wasted volume due to internodes length larger than shoot widths.
Seagrass comprises different species which shows diverse efficiency in space occupation. However, it occupies different bands of biomass-shoot density signifying conditional differentiation of co-occurring seagrass species. Furthermore, high shoot density dominates in favorable environments compare to harsh environment. As a result, this space occupation revealed as a good tool in understanding aspects of seagrasses ecology. Therefore, it serves as the basis to review fundamental aspects including clonal growth pattern, seasonality, competition and depth distribution.
Biomass-density of seagrass meadows is limited by interspecific boundary line making a maximum efficiency of space occupation. Though, species tends to differentiate the bands each scatter plot showing conditional differentiation. Moreover, during summer it shows the most favorable season and lower intertidal in correspond to depth. Therefore, the competence of space occupation requires biomass and shoots density of stands measured by vertical distance to the seagrasses.
Source: Prepared by Joan Tura from BMC Ecology
Volume 18: 24, October 19, 2018
Physical, chemical or biological changes in the environment that will affect its equilibrium are indeed a need of thorough investigations. For it will create a compounded effect from the lower living organisms up to a higher one. This particular article cited the conservation strategies that sustain life on tropical Asian rivers way back two decades ago. River ecology is dominated by flow seasonality imposed by monsoonal rains with profound consequences for fishes and zoobenthos. Riverine biodiversity is threatened by habitat degradation, pollution, flow regulation, river regulation and control as well as over-harvesting. It is emphasized on this article the factors affecting ecological niche of the river based on the survey. At different level from biotic and abiotic features which is very important in determining the flora and fauna.
Threats to tropical Asian Rivers
Water elements and hydrochemistry in relation to its topography and latitude will constitute the wide range factor in ecological balance. Floodplain ecology is economically importance for the breeding and feeding sites of fishes and other aquatic organisms. Between the riparian forests indicates the lateral-interactions for carbon processing as well as trophic production. Two decades ago technologies are not yet fully develop compared today yet problems of river system existed way back time. Seasonal change in Asia will also affect the amount of water in the river catchment.
Mekong River is significantly important for potential energy that is why United Nation makes a committee to investigate. Irrigations, dams have been established all along the Mekong River to control the floods. Yet it cause an environmental impact and environmental consequences which affects balance patterns of nature and its species itself. Like for example the change in inundation patterns that affects productivity. Changes in flow and temperature may remove important directive factors for breeding and migratory behavior of some species.
Proper policy implementation and regulation in River system are very important it must foresee wide range effect to the environment. One single action will affect the whole system of the environment. Though this is still open for argument nowadays since politics and businesses will always contradict for maintaining the pristine ecosystem. Adequate management and efforts in assessing environmental impacts and collaborative studies is indeed necessary. Also a manifestation and proper policy for a good river ecosystem management are deemed needed. This is the challenge and continuing advocacy to limnologists to visualize and assess the sustainability and conservation of river ecosystem.
Source: Prepared by Joan Tura from Springer Hydrobiologia
Volume 248, Issue 3 pp 167–191