Not logged in
PANGAEA.
Data Publisher for Earth & Environmental Science

Acuña, José Luis; Lopez-Urrutia, Angel; Colin, Sean (2014): Data compilation of jellyfish swimming velocities [dataset]. PANGAEA, https://doi.org/10.1594/PANGAEA.832245, In supplement to: Acuña, JL et al. (2011): Faking Giants: The Evolution of High Prey Clearance Rates in Jellyfishes. Science, 333(6049), 1627-1629, https://doi.org/10.1126/science.1205134

Always quote citation above when using data! You can download the citation in several formats below.

RIS CitationBibTeX Citation

Related to:
Colin, Sean P; Costello, John H (2002): Morphology, swimming performance and propulsive mode of six co-occurring hydromedusae. Journal of Experimental Biology, 205, 427-437
Costello, John H; Colin, Sean P (1994): Morphology, fluid motion and predation by the scyphomedusa Aurelia aurita. Marine Biology, 121(2), 327-334, https://doi.org/10.1007/BF00346741
Costello, John H; Colin, Sean P (1995): Flow and feeding by swimming scyphomedusae. Marine Biology, 124(3), 399-406, https://doi.org/10.1007/BF00363913
D'Ambra, Isabella; Costello, John H; Bentivegna, F (2001): An example of collaborative research at the Naples Aquarium: feeding mechanisms of the scyphomedusa Phyllorhiza punctata von Ledenfeld, 1884. Bulletin de l'Institut océanographique Monaco, 1(20), 6pp
Daniel, Anne (1983): Mechanics and energetics of medusan jet propulsion. Canadian Journal of Zoology-Revue Canadienne de Zoologie, 61(6), 1406-1420, https://doi.org/10.1139/z83-190
Ford, M D; Costello, John H; Heidelberg, K B; Purcell, Jennifer E (1997): Swimming and feeding by the scyphomedusa Chrysaora quinquecirrha. Marine Biology, 129(2), 355-362, https://doi.org/10.1007/s002270050175
Gladfelter, W G (1973): A comparative analysis of the locomotory systems of medusoid Cnidaria. Helgoland Marine Research, 25(2-3), 228-272, https://doi.org/10.1007/BF01611199
Graham, William M; Martin, Daniel L; Felder, Darryl L; Asper, Vernon; Perry, Harriet M (2003): Ecological and economic implications of a tropical jellyfish invader in the Gulf of Mexico. Biological Invasions, 5(1/2), 53-69, https://doi.org/10.1023/A:1024046707234
Higgins III, J E; Ford, M D; Costello, John H (2008): Transitions in Morphology, Nematocyst Distribution, Fluid Motions, and Prey Capture during Development of the Scyphomedusa Cyanea capillata. Biological Bulletin, 214(1), 29, https://doi.org/10.2307/25066657
Kolesar, Sarah Elizabeth (2006): DRUM: The effects of low dissolved oxygen on predation interactions between Mnemiopsis leidyi ctenophores and larval fish in the Chesapeake Bay ecosystem. University of Maryland, 172pp
Kremer, Patricia; Costello, John H; Kremer, James N; Canino, Michael (1990): Significance of photosynthetic endosymbionts to the carbon budget of the scyphomedusa Linuche unguiculata. Limnology and Oceanography, 35(3), 609-624, https://doi.org/10.4319/lo.1990.35.3.0609
Kremer, Patricia; Nixon, S (1976): Distribution and abundance of the ctenophore, Mnemiopsis leidyi in Narragansett Bay. Estuarine, Coastal and Shelf Science, 4(6), 627-639, https://doi.org/10.1016/0302-3524(76)90071-2
Kreps, T A; Purcell, Jennifer E; Heidelberg, K B (1997): Escape of the ctenophore Mnemiopsis leidyi from the scyphomedusa predator Chrysaora quinquecirrha. Marine Biology, 128(3), 441-446, https://doi.org/10.1007/s002270050110
Larson, R J (1986): Water content, organic content, and carbon and nitrogen composition of medusae from the northeast Pacific. Journal of Experimental Marine Biology and Ecology, 99(2), 107-120, https://doi.org/10.1016/0022-0981(86)90231-5
Larson, R J (1987): Respiration and carbon turnover rates of medusae from the NE Pacific. Comparative Biochemistry and Physiology Part A: Molecular & Integrative Physiology, 87(1), 93-100, https://doi.org/10.1016/0300-9629(87)90430-0
Martinussen, M B; Bamstedt, Ulf (1999): Nutritional ecology of gelatinous planktonic predators. Digestion rate in relation to type and amount of prey. Journal of Experimental Marine Biology and Ecology, 232(1), 61-84, https://doi.org/10.1016/S0022-0981(98)00101-4
Matanoski, J C; Hood, R R; Purcell, Jennifer E (2001): Characterizing the effect of prey on swimming and feeding efficiency of the scyphomedusa Chrysaora quinquecirrha. Marine Biology, 139(1), 191-200, https://doi.org/10.1007/s002270100558
Matsumoto, Genki I; Harbison, G R (1993): In situ observations of foraging, feeding, and escape behavior in three orders of oceanic ctenophores: Lobata, Cestida, and Beroida. Marine Biology, 117(2), 279-287, https://doi.org/10.1007/BF00345673
McHenry, Matthew J; Jed, Jason (2003): The ontogenetic scaling of hydrodynamics and swimming performance in jellyfish (Aurelia aurita). Journal of Experimental Biology, 206(22), 4125-4137, https://doi.org/10.1242/jeb.00649
Palomares, M L D; Pauly, George G (2008): The growth of jellyfishes. Hydrobiologia, 616(1), 11-21, https://doi.org/10.1007/s10750-008-9582-y
Purcell, Jennifer E (1992): Effects of predation by the scyphomedusan Chrysaora quinquecirrha on zooplankton populations in Chesapeake Bay, USA. Marine Ecology Progress Series, 87, 65-76, https://doi.org/10.3354/meps087065
Purcell, Jennifer E; Shiganova, Tamara; Decker, Mary Beth; Houde, Edward D (2001): The ctenophore Mnemiopsis in native and exotic habitats: US estuaries versus the Black Sea Basin. Hydrobiologia, 451(1/3), 145-176, https://doi.org/10.1023/A:1011826618539
Youngbluth, Marsh J; Bamstedt, Ulf (2001): Distribution, abundance, behavior and metabolism of Periphylla periphylla, a mesopelagic coronate medusa in a Norwegian fjord. Hydrobiologia, 451(1/3), 321-333, https://doi.org/10.1023/A:1011874828960
Parameter(s):
#NameShort NameUnitPrincipal InvestigatorMethod/DeviceComment
Treatment: temperatureT:temp°CAcuña, José Luis
CommentCommentAcuña, José LuisDW = dry weight, WW = wet weight, CW = carbon weight
Aequorea victoria, diameterA. victoria diammmAcuña, José Luissee reference(s)
Aequorea victoria, swimming speedA. victoria swim speedµm/sAcuña, José Luissee reference(s)
Aurelia aurita, diameterA. aurita diammmAcuña, José Luissee reference(s)
Aurelia aurita, body mass, wetA.aurita BM wetmgAcuña, José Luissee reference(s)
Aurelia aurita, body mass, carbonA.aurita BM CmgAcuña, José Luissee reference(s)
Aurelia aurita, swimming speedA.aurita swim speedµm/sAcuña, José Luissee reference(s)
Bolinopsis infundibulum, diameterB. infundibulum diammmAcuña, José Luissee reference(s)
10 Bolinopsis infundibulum, swimming speedB. infundibulum swim speedµm/sAcuña, José Luissee reference(s)
11 Chrysaora quinquecirrha, diameterC. quinquecirrha diammmAcuña, José Luissee reference(s)
12 Chrysaora quinquecirrha, body mass, wetC. quinquecirrha BM wetmgAcuña, José Luissee reference(s)
13 Chrysaora quinquecirrha, body mass, carbonC. quinquecirrha BM CmgAcuña, José Luissee reference(s)
14 Chrysaora quinquecirrha, swimming speedC. quinquecirrha swim speedµm/sAcuña, José Luissee reference(s)
15 Cyanea capillata, diameterC. capillata diammmAcuña, José Luissee reference(s)
16 Cyanea capillata, body mass, wetC. capillata BM wetmgAcuña, José Luissee reference(s)
17 Cyanea capillata, body mass, carbonC. capillata BM CmgAcuña, José Luissee reference(s)
18 Cyanea capillata, swimming speedC. capillata swim speedµm/sAcuña, José Luissee reference(s)
19 Linuche unguiculata, diameterL. unguiculata diammmAcuña, José Luissee reference(s)
20 Linuche unguiculata, body mass, wetL. unguiculata BM wetmgAcuña, José Luissee reference(s)
21 Linuche unguiculata, body mass, carbonL. unguiculata BM CmgAcuña, José Luissee reference(s)
22 Linuche unguiculata, swimming speedL. unguiculata swim speedµm/sAcuña, José Luissee reference(s)
23 Liriope tetraphylla, diameterL. tetraphylla diammmAcuña, José Luissee reference(s)
24 Liriope tetraphylla, swimming speedL. tetraphylla swim speedµm/sAcuña, José Luissee reference(s)
25 Mitrocoma cellularia, diameterM. cellularia diammmAcuña, José Luissee reference(s)
26 Mitrocoma cellularia, swimming speedM. cellularia swim speedµm/sAcuña, José Luissee reference(s)
27 Mnemiopsis leidyi, diameterM. leidyi diammmAcuña, José Luissee reference(s)
28 Mnemiopsis leidyi, body mass, wetM. leidyi BM wetmgAcuña, José Luissee reference(s)
29 Mnemiopsis leidyi, body mass, carbonM. leidyi BM CmgAcuña, José Luissee reference(s)
30 Mnemiopsis leidyi, swimming speedM. leidyi swim speedµm/sAcuña, José Luissee reference(s)
31 Periphylla periphylla, diameterP. periphylla diammmAcuña, José Luissee reference(s)
32 Periphylla periphylla, body mass, wetP. periphylla BM wetmgAcuña, José Luissee reference(s)
33 Periphylla periphylla, body mass, carbonP. periphylla BM CmgAcuña, José Luissee reference(s)
34 Periphylla periphylla, swimming speedP. periphylla swim speedµm/sAcuña, José Luissee reference(s)
35 Phialidium gregarium, diameterP. gregarium diammmAcuña, José Luissee reference(s)
36 Phialidium gregarium, swimming speedP. gregarium swim speedµm/sAcuña, José Luissee reference(s)
37 Phyllorhiza punctata, diameterP. punctata diammmAcuña, José Luissee reference(s)
38 Phyllorhiza punctata, body mass, wetP. punctata BM wetmgAcuña, José Luissee reference(s)
39 Phyllorhiza punctata, body mass, carbonP. punctata BM CmgAcuña, José Luissee reference(s)
40 Phyllorhiza punctata, swimming speedP. punctata swim speedµm/sAcuña, José Luissee reference(s)
41 Stomolophus meleagris, diameterS. meleagris diammmAcuña, José Luissee reference(s)
42 Stomolophus meleagris, body mass, wetS. meleagris BM wetmgAcuña, José Luissee reference(s)
43 Stomolophus meleagris, body mass, carbonS. meleagris BM CmgAcuña, José Luissee reference(s)
44 Stomolophus meleagris, swimming speedS. meleagris swim speedµm/sAcuña, José Luissee reference(s)
License:
Creative Commons Attribution 3.0 Unported (CC-BY-3.0)
Size:
419 data points

Data

Download dataset as tab-delimited text — use the following character encoding:


T:temp [°C]
Comment
A. victoria diam [mm]
A. victoria swim speed [µm/s]
A. aurita diam [mm]
A.aurita BM wet [mg]
A.aurita BM C [mg]
A.aurita swim speed [µm/s]
B. infundibulum diam [mm]		10 
B. infundibulum swim speed [µm/s]		11 
C. quinquecirrha diam [mm]		12 
C. quinquecirrha BM wet [mg]		13 
C. quinquecirrha BM C [mg]		14 
C. quinquecirrha swim speed [µm/s]		15 
C. capillata diam [mm]		16 
C. capillata BM wet [mg]		17 
C. capillata BM C [mg]		18 
C. capillata swim speed [µm/s]		19 
L. unguiculata diam [mm]		20 
L. unguiculata BM wet [mg]		21 
L. unguiculata BM C [mg]		22 
L. unguiculata swim speed [µm/s]		23 
L. tetraphylla diam [mm]		24 
L. tetraphylla swim speed [µm/s]		25 
M. cellularia diam [mm]		26 
M. cellularia swim speed [µm/s]		27 
M. leidyi diam [mm]		28 
M. leidyi BM wet [mg]		29 
M. leidyi BM C [mg]		30 
M. leidyi swim speed [µm/s]		31 
P. periphylla diam [mm]		32 
P. periphylla BM wet [mg]		33 
P. periphylla BM C [mg]		34 
P. periphylla swim speed [µm/s]		35 
P. gregarium diam [mm]		36 
P. gregarium swim speed [µm/s]		37 
P. punctata diam [mm]		38 
P. punctata BM wet [mg]		39 
P. punctata BM C [mg]		40 
P. punctata swim speed [µm/s]		41 
S. meleagris diam [mm]		42 
S. meleagris BM wet [mg]		43 
S. meleagris BM C [mg]		44 
S. meleagris swim speed [µm/s]
Digitized from fig. 3 in Colin and Costello (2002). No body carbon, WW or length-weight regressions were available.5.000E11.060E-4
Instantaneous swimming velocities digitized from time-series measurements of a single individual in fig. 2 of Costello and Colin (1994) and averaged. Conversion from bell diameter to WW according to Palomares and Pauly (2009) and references therein.1.600E12.060E-43.370E-71.900E-5
16WW and average swimming velocity digitized from fig. 8 in McHenry and Jed (2003) and WW transformed to bell diameter (at rest) using equation in Table 1 of Palomares and Pauly (2009).1.300E11.140E-41.870E-78.660E-5
16WW and average swimming velocity digitized from fig. 8 in McHenry and Jed (2003) and WW transformed to bell diameter (at rest) using equation in Table 1 of Palomares and Pauly (2009).1.410E11.450E-42.370E-78.670E-5
16WW and average swimming velocity digitized from fig. 8 in McHenry and Jed (2003) and WW transformed to bell diameter (at rest) using equation in Table 1 of Palomares and Pauly (2009).1.590E12.010E-43.290E-79.250E-5
16WW and average swimming velocity digitized from fig. 8 in McHenry and Jed (2003) and WW transformed to bell diameter (at rest) using equation in Table 1 of Palomares and Pauly (2009).1.360E11.320E-42.160E-79.630E-5
16WW and average swimming velocity digitized from fig. 8 in McHenry and Jed (2003) and WW transformed to bell diameter (at rest) using equation in Table 1 of Palomares and Pauly (2009).7.580E11.580E-22.590E-51.070E-4
16WW and average swimming velocity digitized from fig. 8 in McHenry and Jed (2003) and WW transformed to bell diameter (at rest) using equation in Table 1 of Palomares and Pauly (2009).2.790E19.720E-41.590E-61.170E-4
16WW and average swimming velocity digitized from fig. 8 in McHenry and Jed (2003) and WW transformed to bell diameter (at rest) using equation in Table 1 of Palomares and Pauly (2009).1.110E24.560E-27.450E-51.190E-4
16WW and average swimming velocity digitized from fig. 8 in McHenry and Jed (2003) and WW transformed to bell diameter (at rest) using equation in Table 1 of Palomares and Pauly (2009).3.300E11.550E-32.540E-61.200E-4
16WW and average swimming velocity digitized from fig. 8 in McHenry and Jed (2003) and WW transformed to bell diameter (at rest) using equation in Table 1 of Palomares and Pauly (2009).5.950E18.040E-31.310E-51.340E-4
16WW and average swimming velocity digitized from fig. 8 in McHenry and Jed (2003) and WW transformed to bell diameter (at rest) using equation in Table 1 of Palomares and Pauly (2009).3.970E12.610E-34.260E-61.370E-4
16WW and average swimming velocity digitized from fig. 8 in McHenry and Jed (2003) and WW transformed to bell diameter (at rest) using equation in Table 1 of Palomares and Pauly (2009).3.840E12.370E-33.880E-61.400E-4
16WW and average swimming velocity digitized from fig. 8 in McHenry and Jed (2003) and WW transformed to bell diameter (at rest) using equation in Table 1 of Palomares and Pauly (2009).2.220E15.170E-48.450E-71.570E-4
16WW and average swimming velocity digitized from fig. 8 in McHenry and Jed (2003) and WW transformed to bell diameter (at rest) using equation in Table 1 of Palomares and Pauly (2009).3.910E12.490E-34.070E-61.620E-4
16WW and average swimming velocity digitized from fig. 8 in McHenry and Jed (2003) and WW transformed to bell diameter (at rest) using equation in Table 1 of Palomares and Pauly (2009).2.010E13.910E-46.380E-71.670E-4
16WW and average swimming velocity digitized from fig. 8 in McHenry and Jed (2003) and WW transformed to bell diameter (at rest) using equation in Table 1 of Palomares and Pauly (2009).9.860E13.300E-25.390E-51.740E-4
16WW and average swimming velocity digitized from fig. 8 in McHenry and Jed (2003) and WW transformed to bell diameter (at rest) using equation in Table 1 of Palomares and Pauly (2009).1.300E27.160E-21.170E-41.900E-4
16WW and average swimming velocity digitized from fig. 8 in McHenry and Jed (2003) and WW transformed to bell diameter (at rest) using equation in Table 1 of Palomares and Pauly (2009).7.540E11.560E-22.550E-52.590E-4
16WW and average swimming velocity digitized from fig. 8 in McHenry and Jed (2003) and WW transformed to bell diameter (at rest) using equation in Table 1 of Palomares and Pauly (2009).1.070E24.090E-26.690E-52.780E-4
16WW and average swimming velocity digitized from fig. 8 in McHenry and Jed (2003) and WW transformed to bell diameter (at rest) using equation in Table 1 of Palomares and Pauly (2009).2.290E15.600E-49.150E-72.780E-4
Ctenophore. Swimming velocity from Matsumoto and Harbison (1993). No size data were available.0.000E08.500E-5
21Instantaneous swimming velocities digitized from time-series measurements of a single individual in fig. 1 of Ford et al. (1997). WW from bell diameter using equation in Purcell (1992) .5.450E11.250E-23.500E-52.660E-5
24Bell diameter and average swimming velocity from fig.s 1. 2 and 3 in Matanoski et al. (2001). WW from bell diameter using equation in Purcell (1992).8.000E14.140E-21.160E-41.300E-4
24Bell diameter and average swimming velocity from fig.s 1. 2 and 3 in Matanoski et al. (2001). WW from bell diameter using equation in Purcell (1992).1.000E28.290E-22.320E-41.800E-4
24Bell diameter and average swimming velocity from fig.s 1. 2 and 3 in Matanoski et al. (2001). WW from bell diameter using equation in Purcell (1992).7.000E12.730E-27.640E-51.450E-4
19Instantaneous swimming velocities digitized from time-series measurements of a single individual in fig. 3 of Higgins III et al. (2008) and averaged. Conversion from bell diameter to WW according to Martinussen and Båmstedt (1995).2.600E12.080E-31.120E-57.710E-5
Instantaneous swimming velocities digitized from time-series measurements of a single individual in Fig. 9 of Costello & Colin (1995). Fresh weight supplied in the paper and transformed to DW and to CW according to general equations in Larson (1986).3.900E16.810E-33.660E-51.310E-4
Instantaneous swimming velocities digitized from time-series measurements of a single individual in fig. 6 of Costello and Colin (1995). From diameter to WW and to CW using conversions in Kremer et al. (1990).1.500E16.640E-33.720E-51.240E-4
From Gladfelter (1973) as cited in Daniel (1983). No body carbon, WW or length-weight regressions were available.2.000E12.900E-4
Digitized from fig. 3 in Colin and Costello (2002). No body carbon, WW or length-weight regressions were available.2.140E13.900E-5
24Body length and swimming velocity from Kolesar (2006). From body length to WW using equation in Purcell et al. (2001). From WW to DW according to Palomares and Pauly (2009). From DW to CW according to Kremer and Nixon (1976).2.620E11.520E-28.790E-61.340E-4
24Body length and swimming velocity from Kolesar (2006). From body length to WW using equation in Purcell et al. (2001). From WW to DW according to Palomares and Pauly (2009). From DW to CW according to Kremer and Nixon (1976).3.220E12.230E-21.290E-51.530E-4
24Body length and swimming velocity from Kolesar (2006). From body length to WW using equation in Purcell et al. (2001). From WW to DW according to Palomares and Pauly (2009). From DW to CW according to Kremer and Nixon (1976).3.220E12.230E-21.290E-51.630E-4
24Body length and swimming velocity from Kolesar (2006). From body length to WW using equation in Purcell et al. (2001). From WW to DW according to Palomares and Pauly (2009). From DW to CW according to Kremer and Nixon (1976).2.670E11.570E-29.090E-61.710E-4
24Body length and swimming velocity from Kolesar (2006). From body length to WW using equation in Purcell et al. (2001). From WW to DW according to Palomares and Pauly (2009). From DW to CW according to Kremer and Nixon (1976).2.030E19.390E-35.430E-61.730E-4
24Body length and swimming velocity from Kolesar (2006). From body length to WW using equation in Purcell et al. (2001). From WW to DW according to Palomares and Pauly (2009). From DW to CW according to Kremer and Nixon (1976).2.670E11.570E-29.090E-61.780E-4
24Body length and swimming velocity from Kolesar (2006). From body length to WW using equation in Purcell et al. (2001). From WW to DW according to Palomares and Pauly (2009). From DW to CW according to Kremer and Nixon (1976).3.270E12.290E-21.320E-51.780E-4
24Body length and swimming velocity from Kolesar (2006). From body length to WW using equation in Purcell et al. (2001). From WW to DW according to Palomares and Pauly (2009). From DW to CW according to Kremer and Nixon (1976).3.020E11.980E-21.150E-51.830E-4
24Body length and swimming velocity from Kolesar (2006). From body length to WW using equation in Purcell et al. (2001). From WW to DW according to Palomares and Pauly (2009). From DW to CW according to Kremer and Nixon (1976).3.120E12.100E-21.210E-51.880E-4
24Body length and swimming velocity from Kolesar (2006). From body length to WW using equation in Purcell et al. (2001). From WW to DW according to Palomares and Pauly (2009). From DW to CW according to Kremer and Nixon (1976).2.430E11.310E-27.600E-62.040E-4
24Body length and swimming velocity from Kolesar (2006). From body length to WW using equation in Purcell et al. (2001). From WW to DW according to Palomares and Pauly (2009). From DW to CW according to Kremer and Nixon (1976).2.180E11.070E-26.190E-62.070E-4
24Body length and swimming velocity from Kolesar (2006). From body length to WW using equation in Purcell et al. (2001). From WW to DW according to Palomares and Pauly (2009). From DW to CW according to Kremer and Nixon (1976).2.030E19.390E-35.430E-62.090E-4
24Body length and swimming velocity from Kolesar (2006). From body length to WW using equation in Purcell et al. (2001). From WW to DW according to Palomares and Pauly (2009). From DW to CW according to Kremer and Nixon (1976).3.120E12.100E-21.210E-52.110E-4
24Body length and swimming velocity from Kolesar (2006). From body length to WW using equation in Purcell et al. (2001). From WW to DW according to Palomares and Pauly (2009). From DW to CW according to Kremer and Nixon (1976).3.520E12.630E-21.520E-52.160E-4
24Body length and swimming velocity from Kolesar (2006). From body length to WW using equation in Purcell et al. (2001). From WW to DW according to Palomares and Pauly (2009). From DW to CW according to Kremer and Nixon (1976).3.220E12.230E-21.290E-52.350E-4
24Body length and swimming velocity from Kolesar (2006). From body length to WW using equation in Purcell et al. (2001). From WW to DW according to Palomares and Pauly (2009). From DW to CW according to Kremer and Nixon (1976).2.620E11.520E-28.790E-62.520E-4
24Body length and swimming velocity from Kolesar (2006). From body length to WW using equation in Purcell et al. (2001). From WW to DW according to Palomares and Pauly (2009). From DW to CW according to Kremer and Nixon (1976).3.120E12.100E-21.210E-52.630E-4
23From Kreps et al. (1997). Body length and swimming velocity from Kolesar (2006). From body length to WW using equation in Purcell et al. (2001). From WW to DW according to Palomares and Pauly (2009). From DW to CW according to Kremer and Nixon (1976).2.080E19.840E-35.690E-66.000E-5
8Swimming velocity from text in Youngbluth and Båmstedt (2001). We assumed the average size observed.3.000E13.460E-31.940E-51.670E-4
Digitized from fig. 3 in Colin and Costello (2002). No body carbon, WW or length-weight regressions were available.1.720E11.450E-4
19From DAmbra et al. (2001). From diameter to WW according to Palomares and Pauly (2009). From WW to DW and from DW to CW according to Graham (2003).2.800E12.420E-31.160E-51.730E-4
23Swimming velocities and diameters from fig. 4 in Larson (1987). WW supplied in the paper. From WW to DW and to CW following general conversions in Larson (1986).2.010E12.280E-31.110E-54.810E-4
23Swimming velocities and diameters from fig. 4 in Larson (1987). WW supplied in the paper. From WW to DW and to CW following general conversions in Larson (1986).2.440E14.290E-32.080E-57.090E-4
23Swimming velocities and diameters from fig. 4 in Larson (1987). WW supplied in the paper. From WW to DW and to CW following general conversions in Larson (1986).2.990E18.270E-34.010E-57.830E-4
23Swimming velocities and diameters from fig. 4 in Larson (1987). WW supplied in the paper. From WW to DW and to CW following general conversions in Larson (1986).3.470E11.330E-26.450E-58.160E-4
23Swimming velocities and diameters from fig. 4 in Larson (1987). WW supplied in the paper. From WW to DW and to CW following general conversions in Larson (1986).3.990E12.090E-21.010E-48.370E-4
23Swimming velocities and diameters from fig. 4 in Larson (1987). WW supplied in the paper. From WW to DW and to CW following general conversions in Larson (1986).4.480E13.050E-21.480E-47.340E-4
23Swimming velocities and diameters from fig. 4 in Larson (1987). WW supplied in the paper. From WW to DW and to CW following general conversions in Larson (1986).4.870E13.980E-21.930E-41.090E-3
23Swimming velocities and diameters from fig. 4 in Larson (1987). WW supplied in the paper. From WW to DW and to CW following general conversions in Larson (1986).5.470E15.820E-22.820E-41.160E-3
23Swimming velocities and diameters from fig. 4 in Larson (1987). WW supplied in the paper. From WW to DW and to CW following general conversions in Larson (1986).5.980E17.740E-23.750E-41.030E-3
23Swimming velocities and diameters from fig. 4 in Larson (1987). WW supplied in the paper. From WW to DW and to CW following general conversions in Larson (1986).6.330E19.300E-24.510E-41.100E-3
23Swimming velocities and diameters from fig. 4 in Larson (1987). WW supplied in the paper. From WW to DW and to CW following general conversions in Larson (1986).6.880E11.220E-15.900E-41.180E-3
23Swimming velocities and diameters from fig. 4 in Larson (1987). WW supplied in the paper. From WW to DW and to CW following general conversions in Larson (1986).7.330E11.500E-17.250E-41.120E-3
23Swimming velocities and diameters from fig. 4 in Larson (1987). WW supplied in the paper. From WW to DW and to CW following general conversions in Larson (1986).7.970E11.960E-19.490E-41.220E-3
23Swimming velocities and diameters from fig. 4 in Larson (1987). WW supplied in the paper. From WW to DW and to CW following general conversions in Larson (1986).9.710E13.700E-11.790E-31.130E-3
23Swimming velocities and diameters from fig. 4 in Larson (1987). WW supplied in the paper. From WW to DW and to CW following general conversions in Larson (1986).8.830E12.720E-11.320E-31.440E-3
23Swimming velocities and diameters from fig. 4 in Larson (1987). WW supplied in the paper. From WW to DW and to CW following general conversions in Larson (1986).1.030E24.470E-12.170E-31.150E-3
23Swimming velocities and diameters from fig. 4 in Larson (1987). WW supplied in the paper. From WW to DW and to CW following general conversions in Larson (1986).1.090E25.450E-12.640E-31.240E-3
23Swimming velocities and diameters from fig. 4 in Larson (1987). WW supplied in the paper. From WW to DW and to CW following general conversions in Larson (1986).1.130E25.990E-12.900E-31.270E-3
23Swimming velocities and diameters from fig. 4 in Larson (1987). WW supplied in the paper. From WW to DW and to CW following general conversions in Larson (1986).1.200E27.390E-13.580E-31.080E-3
23Swimming velocities and diameters from fig. 4 in Larson (1987). WW supplied in the paper. From WW to DW and to CW following general conversions in Larson (1986).1.260E28.520E-14.130E-31.220E-3
Instantaneous swimming velocities digitized from time-series measurements of a single individual in Fig. 2 of Costello & Colin (1995). Fresh weight supplied in the paper. and transformed to DW and to CW according to general equations in Larson (1986).3.300E11.660E-18.040E-42.390E-4