Sensory ecology of a semi-aquatic spider (Dolomedes triton)

Summary Preferred ambush sites of fishing spiders Dolomedes triton (Pisauridae) were investigated, primarily with respect to aquatic vegetation and wave action, at five locations differing in these variables along the shore of Dow Lake (near Athens, Ohio). The linear density of spiders correlated positively with the presence of aquatic vegetation. D. triton most often stood at a distance from shore proportional to the width of the zone of floating and emergent vegetation (Fig. 2). Usually they positioned their bodies in the horizontal plane on floating living or dead plant parts. Spider density was negatively correlated with the amplitude of wind-generated waves (Fig. 4). The maximum energy of these waves measured on breezy days was at a frequency of 1.4 Hz, with no components exceeding 10 Hz (Fig. 5). Spiders could discriminate high-amplitude (up to 40 mm) wind waves from prey waves, probably since the latter have substantially higher frequencies (Figs. 3, 5).     

Estimation of the nutrient inputs into river systems – experiences from German rivers

The nutrient discharges from point and diffuse sources in more than 200 German river basins were estimated for the periods 1983–1987 and 1993–1997 employing the MONERIS model. This model distinguishes between six diffuse pathways and point source emissions from waste water treatment plants and direct industrial discharges. It was estimated that the total nitrogen input into the German river systems amounts to about 819,000 t N year^–1 in the period 1993 to 1997. These emissions have decreased since the mid-eighties by about 266,000 t N year^–1, mainly caused by the reduction of point discharges. For phosphorus the emissions have been reduced by 56,290 t P year^–1 and amount to 37,250 t P year^–1 in the period 1993–1997. Based on emission data a retention module estimates riverine nutrient loads. The comparison of the model output with the observed loads shows a deviation as low as 30% and 50% for nitrogen and phosphorus, respectively. The regional resolution of the model indicates the relative importance of different pathways for phosphorus and nitrogen input into river systems. Electronic Publication