Controlling Eutrophication via Surface Aerators in Irregular-Shaped Urban Ponds

Surface aerators have often been introduced in urban ponds for esthetics, but their roles in remediating water quality are less understood. Effects of surface aerators on controlling eutrophication were examined in two urban ponds, in which anaerobic odors and cyanobacterial blooms had occurred and several aerators had been installed. In one of the ponds, a dramatic improvement in dissolved oxygen (DO) (from 1.8 to 8.1 mg L−1) and total phosphorus (TP) (from 1.6 to 0.4 mg L−1) was evident based on the comparison before and after the aeration. Although cyano-bloom did not occur, phytoplankton was dominated by cyanobacteria Microcystis species in both periods. Chlorophyll a (Chl-a) increased (from 29 to 51 μg L−1) and water transparency decreased (from 81 to 27 cm) after the aeration. In the other pond with an irregular shape, water quality was monitored two years after the installation to examine seasonal variation in trophic state and its spatial variation associated with aerator distribution. The water was mixed vertically well for the whole pond, as indicated by small surface-to-bottom differences in temperature. DO decreased in summer after rainfall but was always >5.7 mg L−1. Total nitrogen (TN) and TP were 0.8–2.3 and 0.03–0.07 mg L−1, respectively, and no cyano-blooms were observed across sites throughout the year. Phytoplankton was dominated by green algae and diatom species, which may be favored by the lower phosphorus level of the pond. Chl-a was higher and transparency was lower in the north side, which had more aerators and less shade from trees and buildings. These results suggest that surface aerators increased DO by vertical and horizontal mixing of water, reduced phosphorus release from sediment, and prevented cyano-bloom occurrence, but they did not improve Chl-a level and transparency. Rather, aeration can promote algal growth, and thus, additional purifying measures such as filtration and contact oxidation are required to further improve the trophic state of these ponds.

Prey Refuges in Emergent Vegetation Enhance Diving Beetle (Coleoptera: Dytiscidae) Diversity in Urban Ponds in the Presence of Predatory Fish

Aquatic plants are important prey refugia for aquatic organisms, and their species richness is positively related with aquatic invertebrate species richness. Yet, little is known about how the quantity of refugia, i.e. aquatic vegetation cover, affect aquatic invertebrate assemblages and their habitat use in different levels of predation risks. Here, we investigated how provision of refugia affects diving beetle (Dytiscidae) species richness and abundance in the presence and absence of fish predators. We found that plant cover affected dytiscid populations differently: (1) At the pond level, dytiscid presence was positively correlated with increasing plant cover, both with and without fish, indicating the importance of emergent plants for aquatic biodiversity. (2) At the microhabitat level, dytiscid species richness and abundance responded positively to increasing plant cover in ponds with fish, but there was no such relationship in fishless ponds, emphasizing that the level of predation risks can alter prey species’ use of prey refugia. Our findings provide evidence that the availability of both vegetated and non-vegetated microhabitats can benefit a diversity of aquatic invertebrates. We suggest maintaining variation in provision of emergent plant cover to retain high habitat heterogeneity in urban ponds to enhance freshwater biodiversity.

Introduced fish assemblages in a mosaic of urban ponds: evidence for species-area and diversity-dominance patterns

We studied species-area and diversity-dominance patterns in fish communities of a mosaic of urban ponds (Rome, Italy). We detected 10 fish species (all introduced) in 40 isolated ponds (12.9% of the total; n = 311). The log-transformed species-area relationship (logS = 0.04 logA + 0.16) was significant. Assuming the lack of mechanisms of natural immigration between totally isolated ponds, the number of fish species in this mosaic of ponds may depend exclusively on progressive extinctions and on random and arbitrary events of introduction (acting as human-mediated immigration), these latter explaining the apparently low taxon-related isolation indicated by a low z value (= 0.04). We observed a significantly lower number of species in the smallest ponds and a further threshold under 1 ha in size: these values could represent an interesting threshold for pond management. The diversity-dominance approach evidenced pond size effect acting as a factor of stress on these assemblages.