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Trap Efficiency (trap + efficiency)
Selected AbstractsEvaluation of window flight traps for effectiveness at monitoring dead wood-associated beetles: the effect of ethanol lure under contrasting environmental conditionsAGRICULTURAL AND FOREST ENTOMOLOGY, Issue 2 2009C. Bouget Abstract 1,Subsequent to the diversity of saproxylic beetles being proposed as a management tool in forestry, more explicit knowledge about the efficiency and selective properties of beetle sampling methods is needed. 2,We compared saproxylic beetle assemblages caught by alcohol-baited or unbaited window traps in different forest contexts. Considering that trap attractiveness depends on kairomone concentrations, we appraised whether the trap efficiency was influenced by trap environment (openness and local supply of fresh dead wood). 3,Saproxylic beetles were sampled using 48 cross-vane window flight traps, arranged in paired designs (alcohol-baited/unbaited), in eight ancient and eight recent gaps (open stands), and eight closed-canopy control stands in an upland beech forest in the French Pyrenees. 4,Baited traps were more efficient than unbaited traps in terms of abundance and richness in our deciduous forests. The ethanol lure did not have any repellent effect on the individual response of saproxylic taxa. 5,The influence of local environmental conditions on trap attractiveness was observed. Openness had a significant moderate effect on species richness. Trap attractiveness was slightly reduced in the alcohol-saturated environment of recent gaps probably due to a disruption by local fresh dead-wood concentrations of the kairomonal response of saproxylic beetles to baited traps (,alcohol disruption'). 6,Because the ethanol lure enhanced the probability of species detection, it may be useful in early-warning surveillance, monitoring and control of wood borers, despite slight influences of local conditions on baited trap efficiency. [source] Experiments on sediment trap efficiency in reservoirsLAKES & RESERVOIRS: RESEARCH AND MANAGEMENT, Issue 1 2005Horacio Toniolo Abstract Sediment trap efficiency plays a key role in the effective operational life of reservoirs. This paper presents the results of five laboratory experiments on trap efficiency. An over-spilling condition and four gaps located at the downstream end of a reservoir were analysed in this study. The experimental design assumed a river carrying two phases of sediment flowing into a one-dimensional reservoir. The coarse sediment (sand) was deposited and formed a defined prograding delta. The fine sediment (mud) formed a dilute suspension of wash load in the river. As the river entered the reservoir, the muddy water plunged on the foreset, forming a turbidity current. The turbidity current deposits, in turn, formed a bottomset. Black coal slag and white glass beads were used to simulate sand and mud. Their specific densities were 2.6 and 2.5 for black coal and beads, respectively. The water surface elevation in the reservoir was approximately similar in all experiments. Neither the water nor sediment discharge conditions were changed during the experimental runs. Suspended sediment was sampled through seven siphons; six of these being components of a rake in which they were vertically stacked. The last siphon was positioned on the rake outlet. Sediment samples were taken three times, at approximately evenly spaced intervals in the experiments. Suspended sediment concentration and grain size distribution were calculated for each siphon. The bed sediment deposit was sampled after each experiment. Sediment trap efficiency in the reservoir was calculated. Experimental results show the maximum venting capacity (minimum trap efficiency) occurs under over-spilling conditions. [source] | ||||||||||