Journal of Japan Society on Water Environment Volume 22, Issue 8

Effect of Hydrogeochemical Properties of Watersheds on Inland Water Acidification

In future, freshwaters in Japan are likely to become acidified by increasing acid deposition in eastern Asia. In order to predict the long-term acidification of freshwaters, it is necessary to evaluate acid neutralization mechanism in Japanese watersheds.
In this paper, an estimation method for acid-neutralization by chemical weathering is proposed, and applied to acidified and non-acidified watersheds in order to compare acid-neutralization mechanism. The principal results are :
(1) Japanese non-acidified watersheds receive approximately the same amount of acidic deposition as an acidified watershed in U.S.A..
(2) In Japanese non-acidified watersheds, acid deposition is neutralized by chemical weathering of primary minerals. On the other hand, in the acidified watershed, chemical weathering rates of primary minerals are much smaller than those in Japanese non-acidified watersheds. Therefore, acid deposition is not neutralized in this watershed.
(3) Typical properties of watersheds vulnerable to acidification are :
1) Dominant primary minerals in soil and bedrock are stable against acid deposition.
2) Soil thickness (weathering zone) is relatively small.
3) The ratio of chemical weathering ratio to acidic deposition is relatively small.

Shading Effect of the Deposition on Leaves on the Survival of Eelgrass (Zostera marina L.) in Hiroshima Bay

The objective of this study is to investigate the shading effect of the deposition on leaves on the survival of eelgrass to clarify the factors responsible for the loss of eelgrass habitat in an eutrophic coastal zone with small disturbance by flow and waves in Hiroshima Bay. We investigated environmental conditions of a healthy eelgrass bed as a reference site and a site located outside of the bed with no vegetation. Also, we transplanted eelgrass into these sites and observed their survival.
The transplanted eelgrass into the unvegetated site was difficult to survive, whereas those in the vegetated site could survive. The poor survival in the unvegetated site was due to the high levels of suspended solids deposited on the leaves of eelgrass. The higher deposit resulted in 64% decrease in the light intensity on leaves. The shading resulted in the decrease in the daily periods of irradiance-saturated photosynthesis required for eelgrass growth in the unvegetated site clown to 68-19% of that in the vegetated site.
Contents of silt and accumulation of mud in the unvegetated site was higher than that in vegetated site. It is most probable, therefore, that effect of flow in the unvegetated site was lower and not enough to prevent the deposition in leaves.

Separation Properties of Particulate Suspension Containing Dissolved Organic Matter Due to Double Layer Membrane with Function of Filtration and Adsorption

Filtration experiments were conducted using the double layer membrane consisted of the microfiltration membrane and the activated carbon membrane. Such separation properties as the filtration rate and the rejection were examined using silicon dioxide suspensions containing phenol. The double layer membrane was found to be quite efficient for the separation of the particulate suspensions including the dissolved organic matter. The silicon dioxide particles were rejected by the sieve effects of the microfiltration membrane, whereas phenol was rejected by the adsorption effects of the activated carbon membrane. High phenol concentration caused the reduction of the phenol rejection as filtration proceeded. Although the filtration rate increased with the increase of the filtration pressure, the phenol rejection in the incipient stage of filtration became relatively small under high pressure conditions. It was also shown that the adsorption rate obtained in filtration experiments was significantly larger than that in static adsorption experiments.