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Herring Behaviour in the Dark: Responses to Stationary and Continuously Vibrating Obstacles

Published online by Cambridge University Press:  11 May 2009

J. H. S. Blaxter
Affiliation:
Scottish Marine Biological Association, Dunstaffnage Marine Research Laboratory, P.O. Box 3, Oban, Argyll PA34 4AD
R. S. Batty
Affiliation:
Scottish Marine Biological Association, Dunstaffnage Marine Research Laboratory, P.O. Box 3, Oban, Argyll PA34 4AD

Extract

The behaviour of herring subjected to stationary and vibrating obstacles in their swimming path was recorded in daylight and darkness using an infra-red sensitive TV system. The herring avoided stationary obstacles using visual stimuli and usually collided with such obstacles in darkness. They showed strong avoidance to a continuously vibrating sound source in darkness but the speed of turning was relatively slow and there was no evidence for habituation. As they approached the source they usually responded when the sound pressure reached 10–20 Pa, about 70 dB above the threshold. Particle velocity within the lateral line canals was calculated and was 40–60 dB above threshold. Herring seem to be able to adapt their avoidance behaviour to suit the urgency of the situation.

Type
Research Article
Copyright
Copyright © Marine Biological Association of the United Kingdom 1985

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References

Batty, R. S., 1983. Observation offish larvae in the dark with television and infra-red illumination. Marine Biology, 76, 105107.CrossRefGoogle Scholar
Batty, R. S., 1984. Development of swimming movements and musculature of larval herring (Clupea harengus). Journal of Experimental Biology, 110, 217229.CrossRefGoogle ScholarPubMed
Beach, M. H., 1978. The use of infra-red light and closed circuit TV to validate records from automatic fish counters. Journal of Fish Biology, 13, 639644.CrossRefGoogle Scholar
Blaxter, J. H. S., 1964. Spectral sensitivity of the herring Clupea harengus L. Journal of Experimental Biology, 41, 155162.CrossRefGoogle ScholarPubMed
Blaxter, J. H. S. & Batty, R. S., 1984. The herring swimbladder: loss and gain of gas. Journal of the Marine Biological Association of the United Kingdom, 64, 441459.CrossRefGoogle Scholar
Blaxter, J. H. S. & Batty, R. S., 1985. The development of startle responses in herring larvae. Journal of the Marine Biological Association of the United Kingdom, 65, 737750.CrossRefGoogle Scholar
Blaxter, J. H. S., Gray, J. A. B. & Best, A. C. G., 1983. Structure and development of the free neuromasts and lateral line system of the herring. Journal of the Marine Biological Association of the United Kingdom, 63, 247260.CrossRefGoogle Scholar
Blaxter, J. H. S., Gray, J. A. B. & Denton, E. J., 1981. Sound and startle responses in herring shoals. Journal of the Marine Biological Association of the United Kingdom, 61, 851869.CrossRefGoogle Scholar
Blaxter, J. H. S. & Hoss, D. E., 1981. Startle response in herring: the effect of sound stimulus frequency, size of fish and selective interference with the acoustico-lateralis system. Journal of the Marine Biological Association of the United Kingdom, 61, 871879.CrossRefGoogle Scholar
Blaxter, J. H. S. & Hunter, J. R., 1982. The biology of the clupeoid fishes. Advances in Marine Biology, 20, 1223.CrossRefGoogle Scholar
Denton, E. J. & Gray, J. A. B., 1983. Mechanical factors in the excitation of clupeid lateral lines. Proceedings of the Royal Society (B), 218, 126.Google ScholarPubMed
Graham, J. M., 1984. The Bobobat – a 9 bit × 9 bit video digitiser for television pictures. Marine Physics Group Report. Scottish Marine Biological Association, no. 24, 15 pp.Google Scholar
Gray, J. A. B., 1984. Interaction of sound pressure and particle acceleration in the excitation of the lateral-line neuromasts of sprats. Proceedings of the Royal Society (B), 220, 299325.Google Scholar
Hawkins, A. D., 1981. The hearing abilities offish. In Hearing and Sound Communication in Fishes (ed. Tavolga, W. N., Popper, A. N. and Fay, R. R.), pp. 109113. Berlin: Springer-Verlag.CrossRefGoogle Scholar
Hoin-Radovsky, I., Bleckmann, H. & Schwartz, E., 1984. Determination of source distance in the surface-feeding fish Pantodon buchholzi Pantodontidae. Animal Behaviour, 32, 840851.CrossRefGoogle Scholar
Partridge, B. L. & Pitcher, T. J., 1980. The sensory basis of fish schools: relative roles of lateral line and vision. Journal of Comparative Physiology, 135, 315325.CrossRefGoogle Scholar
Partridge, B. L., Pitcher, T., Cullen, J. M. & Wilson, J., 1980. The three-dimensional structure of fish schools. Behavioural Ecology and Sociobiology, 6, 277288.CrossRefGoogle Scholar
Pitcher, T., 1979. Sensory information and the organization of behaviour in a shoaling cyprinid fish. Animal Behaviour, 27, 126149.CrossRefGoogle Scholar
Schwarz, A. B. & Greer, G. L., 1984. Responses of Pacific herring Clupea harengus pallasi to some underwater sounds. Canadian Journal of Fisheries and Aquatic Sciences, 41, 11831192.CrossRefGoogle Scholar
Smith, K. A., 1964. The use of air bubble curtains as an aid to fishing. In Modern Fishing Gear of the World, vol. 2, pp. 540544. London: Fishing News Books Ltd.Google Scholar
Sundnes, G. & Bratland, P., 1972. Notes on the gas content and neutral buoyancy in physostome fish. Fiskeridirektoratets skrifter (ser. Havundersøkelser), 16, 8997.Google Scholar