Your search keyword '"Jacobs AF"' showing total 2 results

1. The effect of water turbidity on the near-surface water temperature of larval habitats of the malaria mosquito Anopheles gambiae.

Author

Paaijmans KP, Takken W, Githeko AK, and Jacobs AF

Subjects

Animals, Computer Simulation, Larva growth & development, Surface Properties, Anopheles growth & development, Ecosystem, Models, Chemical, Nephelometry and Turbidimetry, Temperature, Water chemistry, Water parasitology

Abstract

Water temperature is an important determinant in many aquatic biological processes, including the growth and development of malaria mosquito (Anopheles arabiensis and A. gambiae) immatures. Water turbidity affects water temperature, as suspended particles in a water column absorb and scatter sunlight and hence determine the extinction of solar radiation. To get a better understanding of the relationship between water turbidity and water temperature, a series of semi-natural larval habitats (diameter 0.32 m, water depth 0.16 m) with increasing water turbidity was created. Here we show that at midday (1300 hours) the upper water layer (thickness of 10 mm) of the water pool with the highest turbidity was on average 2.8 degrees C warmer than the same layer of the clearest water pool. Suspended soil particles increase the water temperature and furthermore change the temperature dynamics of small water collections during daytime, exposing malaria mosquito larvae, which live in the top water layer, longer to higher temperatures.

Published

2008

2. Dew measurements along a longitudinal sand dune transect, Negev Desert, Israel.

Author

Jacobs AF, Heusinkveld BG, and Berkowicz SM

Subjects

Animals, Ecosystem, Israel, Desert Climate, Water analysis

Abstract

In a desert environment dew can serve as an important source of moisture for plants, biological crusts, insects and small animals. A measurement programme was carried out within a sand dune belt situated in the northwestern Negev desert, Israel, to measure daily amounts of dew deposition as well as micro-meteorological conditions during the dew formation and early-morning drying process. Dew quantities were measured by micro-lysimeters along a 200-m transect as well as by the eddy-correlation technique at a reference location. A simple physical model was constructed to simulate the dew deposition process as well as early-morning drying for the interdune area and the north- and south-facing dune slopes. Measurements carried out during September and October 1997 showed that the daily amounts of dew ranged between 0.1 mm/night and 0.3 mm/night within the interdune area. On the slopes, the amounts of dew were about 50% lower. Simulated results agreed well with the field data.

Published

2000