[KSCI] Korea Science Citation Index Service

http://dx.doi.org/10.3796/KSFOT.2018.54.3.193

Penetrating behavior of target prawns (Sicyonia penicillata) contacting netting panels in an experimental water tunnel

KIM, Yonghae (Institute of Marine Industry, College of Marine Science, Gyeongsang National University)
GORDON, Malcolm S. (Department of Ecology & Evolutionary Biology, University of California)

Publication Information

Journal of the Korean Society of Fisheries and Ocean Technology / v.54, no.3, 2018 , pp. 193-203 More about this Journal

Abstract

Capture efficiencies of commercial shrimp trawls may improve if their designs took into better account behavioral responses of wild shrimp to approaching cod-end of the trawls. Here we report results of water tunnel-based experimental studies of responses of wild California target prawns to several different near-realistic netting configurations over a range of water velocities (0.3-0.7 m/s). Netting panels were oriented at parallel to water flows (FP) on the bottom of test section, vertical (VT) or diagonal sloping backward (DG), bottom to top. Behavioral responses were recorded by video camera and analyzed frame by frame. Measured responses included rates of penetrating through netting by behavioral features and tail-flip frequencies. Frequencies of prawn passing through the nets increased with flow speed for both orientations and were higher at given speeds for sloped nets. Other behavioral features (e.g., passage head-or tail-first) also varied significantly with water velocities and netting orientation. Interactions of penetrating rates between netting orientations and flow speeds also were significantly dependent, except for prawn size. Additional studies are needed of other shrimp species and at higher water velocities more similar to actual field operations using trawls to improve size selectivity.

Keywords

Shrimp behavioral features; Flow speeds; Netting orientations; Penetration rates;

Citations & Related Records

Times Cited By KSCI : 1 (Citation Analysis)

Reference
Cited By KSCI

1	Broadhurst MK, Sterling DJ and Millar RB. 2015. Increasing lateral mesh openings in penaeid trawls to improve selection and reduce drag. Fish Res 170, 68-75. (DOI:10.1016/j.fishres.2015.05.014) DOI
2	Campos A, Fonseca P and Erzini K. 2002. Size selectivity of diamond and square mesh cod ends for rose shrimp (Parapenaeus longirostris) and Norway lobster (Nephrops norvegicus) off the Portuguese south coast. Fish Res 58, 281-301. DOI
3	Catchpole TL and Revill AS. 2008. Gear technology in Nephrops trawl fisheries. Rev Fish Biol and Fish 18, 17-31. (DOI:10.1007/s11160-007-9061-y) DOI
4	Daniel TL and Meyhofer E. 1989. Size limits in escape locomotion of Carridean shrimp. J Exp Biol 143, 245-265.
5	Deval MC, Bok T, Ates C and Ozbilgin H. 2006. Selectivity of PE and PA material codends for rose shrimp (Parapenaus longirostris) in Turkish twin rigged beam trawl fishery. Fish Res 81, 72-79. (DOI:10.1016/j.fishres.2006.05.007) DOI
6	Hannah RW and Jones SA. 2012. Evaluating the behavioral impairment of escaping fish can help measure the effectiveness of bycatch reduction devices. Fish Res 131-133, 39-44. (DOI:10.1016/j.fishres.2012.07.010) DOI
7	He P and Balzano B. 2007. Reducing the catch of small shrimps in the Gulf of Maine pink shrimp fishery with a size-sorting grid device. ICES J MAR Sci 64, 151-1557. (DOI:10.1093/icesjms/fsm098) DOI
8	He P and Balzano B. 2011. Rope Grid: A new grid design to further reduce finfish by catch in the Gulf of Maine pink shrimp fishery. Fish Res 111, 100-107. (DOI: 10.1016/j.fishres.2011.07.001) DOI
9	Isaksen B, Valdemarsen JW, Larse RB and Karlsen L. 1992. Reduction of fish by-catch in shrimp trawl using a rigid separator grid in the aft belly. Fish Res 13, 35-352.
10	Kim YH. 2012. Analysis of turbulence and tilt by in-situ measurements inside the codend of a shrimp beam trawl. Oce Eng 53, 6-15. (DOI:10.1016/j.oceaneng.2012.06.014) DOI
11	Kim YH and Gordon MS. 2010. Swimming and posture control of common carp when penetrating mesh nets in a water tunnel. Fish Res 102, 166-172. (DOI:10.1016/j.fishres.2009.11.009) DOI
12	Kim YH and Gordon MS. 2016. Analysis of tail flip of the target prawn at the time of penetrating mesh in water flow by tank experiments. J Korean Soc Fish Technol 52, 308-317. (DOI:10.3796/KSFT.2016.52.4.308) DOI
13	Kroeger M. 1984. Some results of flow measurement on a full scale pelagic trawl. ICES. CM, B/27. 1-11.
14	Loaec H, Morandeau F, Meillat M and Davies P. 2006. Engineering development of flexible selectivity grids for Nephrops. Fish Res 79, 210-218. (DOI:10.1016/j.fishres.2006.01.011) DOI
15	Nauen JC and Shadwick RE. 2001. The dynamics and scaling of force production during the tail-flip escape response of the California spiny lobster Panulirus. J Exp Biol 204, 1817-1830.
16	Newland PL and Chapman CJ. 1989. The swimming and orientation behavior of the orway lobster, Nephrops norvegicus (L), in relation to trawling. Fish Res 8, 63-80. DOI
17	Revill A and Holst R. 2004. The selective properties of some sieve nets. Fish Res 66, 171-183. (DOI:10.1016/S0165-7836(03)00198-X) DOI
18	O'Neill FG, MaKay SJ, Ward JN, Strickland A, Kynoch RJ and Zuur AF. 2003. An investigation of the relationship between sea state induced vessel motion and cod-end selection. Fish Res 60, 107-130. (DOI:10.1016/S0165-736(02)00056-5) DOI
19	Pichot G, Germain G and Priour D. 2009. On the experimental study of the flow around a fishing net. J Mech B Fluids 28, 103-116. (DOI:10.1016/j.euromechflu.2008.02.002) DOI
20	Queirolo D, Gaete E, Montenegro I, Soriguer MC and Erzini K. 2012. Behaviour of fish by-catch in the mouth of a crustacean tawl. J Fish Biol 80, 2517-2527. (DOI.org/10.1111/j.1095-8649.2012.03305.x) DOI
21	Sala A, Lucchetti A and Perdichizzi A. 2015. Is square-mesh better selective than larger mesh? A perspective on the management for Mediterranean trawl fisheries. Fish Res 161, 182-190.(DOI:10.1016/j.fishres.2014.07.011) DOI
22	Tokai T, Ito H, Masaki Y and Kitahara T. 1990. Mesh selectivity curves of a shrimp beam trawl for Southern rough shrimp Trachypenaeus curvirostris and mantis shrimp Oratosquilla oratoria. Nippon Suisn Gakkasihi 56, 1231-1237. DOI
23	Jensen GC. 2014. Crabs and Shrimps of the Pacific coast. Molamarine. Bremerton, WA. 174-175.
24	Videler J and Wardle CS. 1991. Fish swimming stride by stide : speed limits and endurance. Rev Fish Biol Fish 1, 23-40. DOI
25	Yu X, Zhang X, Zhang P and Yu C. 2009. Critical swimming speed, tail-flip speed and physiological response to exercise fatigue in kuruma shrimp, Marsupenaeus japonicas. Comp Biochem Physiol A 153, 120-124. (DOI:10.1016.j.cbpa.2009.01.012) DOI
26	Zar JH. 1996. Biostatistical analysis (3rdedition). Prentice Hall., London, 471-479.
27	Broadhurst MK. 2000. Modifications to reduce bycatch in prawn trawls: A review and framework for development. Rev Fish Biol and Fish 10, 27-60. (DOI:10.1023/A:1008936820089) DOI
28	Allen A, Hewitt R and Venrick E. 2005. California Cooperative Oceanic Fisheries Investigations. Rep 46, 176.
29	Arnott SA, Neil DM and Ansell AD. 1989. Tail-flip mechanism and size-dependent kinematics of escape swimming in the brown shrimp Crangon crangon. J Exp Biol 201, 1771-1784.
30	Briggs RP. 1986. A general review of mesh selection for Nephrops norvegicus (L). Fish Res 4, 59-73. DOI
31	Broadhurst MK, Kennelly SJ and Eayrs S. 1999. Flow-related effects in prawn-trawl codend: potential for increasing the escape of unwanted fish through square-mesh panels. Fish Bull 97, 1-8.