No Job Name


Metabolism and biomass vertical distribution of zooplankton in
the Bransfield Strait during the austral summer of 2000por_116 415..425
Lidia Yebra,1,2 Santiago Hernández-León,2 Carlos Almeida2 & Pierrick Bécognée2

1 Institut de Ciències del Mar, CSIC, Passeig Marítim de la Barceloneta 37–49, ES-08003 Barcelona, Spain

2 Biological Oceanography Laboratory, Facultad de Ciencias del Mar, Universidad de Las Palmas de Gran Canaria, Campus Universitario de Tafira,

ES-35017 Las Palmas de Gran Canaria, Canary Islands, Spain

Abstract

The vertical distribution (0–550 m) of zooplankton biomass, and indices of
respiration (electron transfer system [ETS]) and structural growth (aminoacyl-
tRNA synthetases activity [AARS]), were studied in waters off the Antarctic
Peninsula during the austral summer of 2000. The dominant species were the
copepod Metridia gerlachei and the euphausiid Euphausia superba. We observed
a vertical krill/copepod substitution in the water column. The zooplankton
biomass in the layer at a depth of 200–500 m was of the same magnitude as the
biomass in the layer at a depth of 0–200 m, indicating that biomass in the
mesopelagic zone is an important fraction of the total zooplankton in Antarctic
waters. The metabolic rates of the zooplankton community were sustained
by less than 0.5% of the primary production in the area, suggesting that
microplankton or small copepods are the main food source. Neither food
availability nor predation seemed to control mesozooplankton biomass. The
wide time lag between the abundance peak of the dominant copepod (M.
gerlachei) and the phytoplankton bloom is suggested to be the main explanation
for the low summer zooplankton biomass observed in these waters.

Keywords
AARS; Antarctic Peninsula; biomass; ETS;

metabolism; zooplankton.

Correspondence
Lidia Yebra, Institut de Ciències del Mar, CSIC,

Passeig Marítim de la Barceloneta 37–49,

ES-08003 Barcelona, Spain. E-mail:

lyebra@icm.csic.es

doi:10.1111/j.1751-8369.2009.00116.x

The Bransfield Strait is located between the South Shet-
land Islands and the Antarctic Peninsula. It presents high
variability in both physical conditions (e.g., mesoscale
eddies and fronts; Zhou et al. 2006) and primary produc-
tion rates (Basterretxea & Arístegui 1999; Varela et al.
2002; Morán et al. 2006). It is also considered to be a
highly productive region for all trophic levels (Huntley
et al. 1990; Zhou et al. 1994). The studies of Antarctic
zooplankton have focused on estimating the impact of
these organisms on the development and evolution of
primary production in areas affected by strong micro- or
mesoscale plankton distribution patterns, or by the
influence of eddies and frontal systems, which are
characteristic features of the Southern Ocean. More
recently, the influence of the physical environment on
zooplankton species distribution, as well as their role in
energy flow, has been studied using indices of physiologi-
cal processes (Bergeron et al. 1985; Schalk 1990; Drits
et al. 1993; Hernández-León et al. 1999; Hernández-León
et al. 2000). However, not all the variability in zooplank-
ton biomass is explained by physical changes.

Zooplankton biomass and abundance in the Bransfield
Strait have been studied during the austral spring and
summer seasons (Alcaraz et al. 1998; Hernández-León
et al. 1999; Hernández-León et al. 2000; Cabal et al.
2002; Calbet et al. 2005), showing a great interannual
variability. Previous studies (Hernández-León et al. 1999;
Hernández-León et al. 2000; Calbet et al. 2005) have
reported low mesozooplankton biomass around the
Antarctic Peninsula. This is probably related to predation
and/or food quality, rather than to food availability.
Hernández-León et al. (2000) studied the distribution of
mesozooplankton biomass and metabolism in the upper
200-m layer, showing low zooplankton biomass with a
rather high growth rate. Yet, zooplankton consumed less
than 10% of the primary production, and a top–down
effect of krill on copepods in the area was suggested. In
addition, an important fraction of the biomass in these
waters was found in the mesopelagic zone (below 200-m
depth), as was observed in previous works on Antarctic
copepods (Lancraft et al. 1989; Lancraft et al. 1991; Lopez
& Huntley 1995; Pakhomov et al. 1996; Lancraft et al.

Polar Research 28 2009 415–425 © 2009 The Authors 415

mailto:lyebra@icm.csic.es


2004) and euphausiids (Hernández-León, Portillo-
Hahnefeld et al. 2001; Hernández-León & Montero
2006). However, most studies to date have been focused
on the upper 200-m layer. The study of biomass and
diel vertical migration of the deep-water meso-
zooplankton (200–550-m depth) could improve our
understanding of the trophic web in this region of the
Southern Ocean.

The main aim of this study is to give a first insight on
zooplankton biomass and metabolic rates in relation to
the vertical distribution over the 0–550-m water column.
We used two enzymatic methods to obtain high-
resolution estimates of respiration and growth at depth.
The activity of the electron transfer system (ETS; Packard
1971) was used to assess the maximum potential respi-
ration. The aminoacyl-tRNA synthetases activity (AARS;
Yebra & Hernández-León 2004) was applied as an index
of the in-situ growth rate. The combined use of these
methods allowed us to simultaneously study in-situ
respiration and growth rates of mixed zooplankton
populations inhabiting mesopelagic depths, without the
need for incubation or elaborate procedures. A recent
discussion of the usefulness and advantages of these bio-
chemical methods can be found in Båmstedt (2000),

Ikeda et al. (2000), Hernández-León, Almeida et al.
(2001, 2002), Yebra, Harris et al. (2005), Yebra et al.
(2006) and Guerra (2006). Secondarily, we seek to inves-
tigate the importance of bottom–up and top–down
controls on zooplankton biomass in the Bransfield Strait.
Finally, despite the short austral summer nights, we
studied the plankton dynamic in the water column by
day and night in an attempt to look at diel vertical
migration and carbon fluxes mediated by zooplankton
in the region.

Methods

Sampling

During the austral summer of 2000, from 24 January to
17 February, 10 stations were sampled on board the RV
BIO Hespérides in the Bransfield Strait, Antarctic Peninsula
(Fig. 1), using a Longhurst–Hardy Plankton Recorder
(LHPR; 200-mm mesh net). The average day length was
20 h (06.00–02.00 h GMT), and darkness lasted for only
4 h (02.00–06.00 h GMT). Eight hauls were carried out
by day (14.33–24.21 h GMT) and two hauls were carried
out at night (03.56–04.39 h GMT), in order to study diel

Fig. 1 Location of the Longhurst–Hardy Plank-
ton Recorder net stations: �, day; �, night.

Antarctic summer zooplankton metabolism L. Yebra et al.

Polar Research 28 2009 415–425 © 2009 The Authors416



differences in biomass and metabolic profiles. Samples
were collected from 550 to 0 m, at a speed of 3–4 knots.
Each haul contained about 22 samples, corresponding
to different layers, ranging from 13- to 24-m deep.
A conductivity–temperature–depth (CTD) recorder was
used to obtain high-resolution profiles of temperature,
conductivity and fluorescence. On board, samples were
split into two halves. One half was stored in liquid nitro-
gen at -196°C, for biochemical assays, and the other half
was preserved in 4% formalin for presence/absence
analyses of the two main groups found: euphausiids
and copepods.

Biomass and metabolic rates

Frozen samples were homogenized with Tris-HCl buffer
(pH = 7.8) before the assays. The protein content was
measured using the folin dye method (Lowry et al. 1951),
as modified for microanalysis by Rutter (1967). We trans-
formed biomass, measured as protein content, to carbon,
using published ratios: protein : dry weight (dw) = 0.192;
carbon : dry weight = 0.40 (Postel et al. 2000).

The ETS activity was assayed using the method of
Packard (1971), as modified by Gómez et al. (1996). ETS
activity was corrected for the in-situ temperature at each
depth using the Arrhenius equation with an activation
energy of 15 kcal mol-1, as given by Packard et al. (1975).
AARS activity was measured using the method of Yebra &
Hernández-León (2004), and was corrected for the in-situ
temperature with an activation energy of 10.5 kcal mol-1

(Guerra 2006).
The community respiration rates (R; mg C m-2 h-1)

were assessed from specific ETS activities (ml O2 mg
prot-1 h-1) and integrated biomass (mg protein m-2),
assuming a respiratory quotient of 0.97 (Omori & Ikeda
1984) and a theoretical R : ETS ratio of 0.5 (Hernández-
León & Gómez 1996; Ikeda et al. 2000). The community
growth rates (nm PPi m-2 h-1) were calculated from
specific AARS activities (nm PPi mg protein-1 h-1) and
integrated biomass (mg protein m-2). We assessed the
community potential ingestion (I; mg C m-2 h-1) from
respiration rates (R), assuming an assimilation and a gross
growth efficiency of 70 and 30%, respectively, and apply-
ing the equation proposed by Ikeda & Motoda (1978):
I = 100 R/(70 - 30) = 2.5 R.

Active flux

Protein content and ETS activity data were averaged at
25-m intervals to obtain day and night vertical distribu-
tion profiles. The biomass night profile was then
subtracted from the biomass day profile to show daily
changes. The day-minus-night protein profile was inte-

grated to estimate migrant biomass (mg protein m-2). The
negative area values represent the migrant biomass that
reached the euphotic layer at night (0–245-m depth).

To assess the respiratory flux (ml O2 m-2 day-1) of
carbon to deep waters, positive values of the ETS
(ml O2 m-3 h-1) day-minus-night profile were integrated
and divided by the integrated biomass present in the
same depth range (as in Yebra, Almeida et al. 2005). The
specific ETS activity measured at depth (ml O2 mg
protein-1 h-1) was then multiplied by the migrant biomass
(mg protein m-2) to obtain the flux resulting from
migrants’ respiration located below 200-m depth during
the day. For all calculations, we applied 4 h of darkness
per day, and an R : ETS ratio of 0.5 (see above).

Results

Hydrology

We found no sea-ice cover during the sampling period.
The water temperature ranged between 1 and 2°C at the
surface, decreasing to -1°C at 500-m depth (Fig. 2). We
observed occasional deep warm water masses at a depth
of 200 m. Salinity ranged from 33.9 to 34.4 at the surface,
but was similar below 100 m at all stations. The
maximum of chlorophyll was observed at around 25-m
depth, where values reached up to 14 mg Chl. a m-3.

Zooplankton biomass

The most abundant organisms were the pelagic copepod
Metridia gerlachei and the euphausiid Euphausia superba.
Calanoides acutus and Calanus propinquus were also
present, but were found only in low numbers. Visual
assessments of the presence/absence of copepods and
euphausiids showed that by day large euphausiids
were in the surface waters (above 250-m depth),
whereas smaller juveniles stayed at depth (500–550 m).
M. gerlachei was located in a compact layer from 300 to
500 m depth. Occasional layers of salps (Salpa thompsonii)
were also found around 100- and 300-m depths (Fig. 3a).
Surprisingly, the biomass values by day were similar in
both the 0–200-m and the 200–550-m layers (t = -0.17,
p = 0.86; Table 1). At night, euphausiids were observed
above 100 m and below 400 m, whereas copepods
dominated the layer in between (150–400 m), and salps
scarcely occurred above 100 m (Fig. 3b). During the
night, the biomass was concentrated in the upper 200-m
layer, increasing by twofold compared with daytime
values (t = 2.85, p < 0.01; Table 1).

Metabolic indices

During the day, specific ETS activities decreased slightly
from the surface down to 200 m, but presented higher

Antarctic summer zooplankton metabolismL. Yebra et al.

Polar Research 28 2009 415–425 © 2009 The Authors 417



values at mesopelagic depths (200–550 m, t = -2.81,
p < 0.01; Fig. 3a). In contrast, specific AARS activities
were higher above 200 m (Fig. 3a), with an averaged
specific AARS activity double that in the 200–550-m layer
(t = 3.83, p < 0.001; Table 1).

At night, the specific ETS remained variable, with peaks
at 25- and 225-m depths. Specific AARS activity peaks
were also higher in the upper 250-m layer (Fig. 3b).
The upward diel migration was accompanied by a 60%
increase in averaged specific ETS activity in the upper
200 m (t = -2.78, p < 0.01), and a slight but not signifi-
cant (t = 0.93, p = 0.35) 15% decrease between 200 and
550 m. The specific AARS activity remained constant
in shallow waters (t = 0.42, p = 0.67) and increased,
although not significantly (t = -1.77, p = 0.079), by 46%
in the mesopelagic zone at night (Table 1).

Community rates and active flux

Considering the whole water column, we observed a
small increase in specific ETS and AARS activities by
night (13% and 9%, respectively; Table 1). However,
as the biomass also increased at night, the respiration
rate of the community was 1.7 times higher during
the night (0.20 mg C m-2 h-1) compared to daytime
(0.12 mg C m-2 h-1). The community growth rate was
also 50% higher by night (360.6 nm PPi m-2 h-1) than by
day (241.8 nm PPi m-2 h-1). The mean community respi-
ration (over 0–550 m) was 1.74 mg C m-2 day-1, and the
community ingestion (0–550 m) assessed from respira-
tion was 4.35 mg C m-2 day-1.

From the day-minus-night biomass differences
observed in the upper 250 m (Fig. 4a) we obtained

a daily migrant biomass of 92.3 mg protein m-2. The
integrated total ETS activity diel difference (Fig. 4b) was
187.8 ml O2 m-2 h-1, and we estimated an active flux to
deep waters of 10.2 mg C m-2 d-1.

Discussion

Relationship between biomass vertical distribution
and enzyme activities

The Antarctic Peninsula is a region of low zooplankton
biomass in comparison with other Antarctic areas (Atkin-
son et al. 1997; Ward et al. 1997; Ward et al. 2004). The
summer zooplankton biomass in the Bransfield Strait
has high interannual variability, ranging from 35 up to
1039 mg C m-2 (Table 2). The highest biomass record cor-
responds to a summer when the salp S. thompsonii was the
most abundant zooplankton species (Alcaraz et al. 1998).
This species can have a widespread oceanic distribution
further north and east of the study area (Hosie 1994).
However, they were scarcely found during our study, and
were mainly associated with relatively warmer waters.
Instead, zooplankton was dominated by crustaceans,
and the biomass values we observed were within the
lower range of the previous values reported in the area
(Table 2).

The patterns of zooplankton vertical distribution
described for Antarctic waters coincide with our observa-
tions in the Bransfield Strait. These studies show a surface
layer dominated by krill, and a wide layer of smaller
organisms below 200-m depth (Pakhomov et al. 1994;
Murray et al. 1995; Weeks et al. 1995; Hernández-León,
Portillo-Hahnefeld et al. 2001). During our sampling,

Fig. 2 Daytime conductivity–temperature–depth (CTD) vertical profiles of temperature (°C), salinity and chlorophyll a (mg Chl. a m-3).

Antarctic summer zooplankton metabolism L. Yebra et al.

Polar Research 28 2009 415–425 © 2009 The Authors418



euphausiids (E. superba) were concentrated above 200 m
and around 550-m depth. The copepod M. gerlachei was
found in the 300–500-m layer, as previously observed
(Schnack-Schiel & Mújica 1994; Lopez & Huntley 1995;
Hernández-León, Portillo-Hahnefeld et al. 2001), and was
the dominant copepod species during our sampling. This
agrees with Pakhomov et al. (2000), who observed that
this copepod could make up 40–95% of the total abun-
dance in the absence of krill swarms. Despite the reduced
krill presence below 200-m depth, the biomass in the
mesopelagic zone was similar to that in upper waters. This
is in agreement with studies showing that copepods could
represent more than 50% of the total biomass in Antarctic
waters (Boysen-Ennen et al. 1991; Conover & Huntley
1991; Pakhomov et al. 2000).

The vertical distribution of ETS activities was related to
biomass concentrations. The highest specific respiration

rates (ETS activities) were found below 200 m, and
were mainly related to copepod populations. Because of
the inverse allometric relationship between size and
metabolism (Ikeda 1985), copepods would show a higher
metabolism than euphausiids, thereby explaining the
observed tendency of specific respiration rates to increase
with depth. Specific ETS activity increases in relation to
high biomass values were previously observed in the
Weddell Sea (Jacques & Panouse 1991; Schnack-Shiel
& Mújica 1994). The night-time increase in biomass
from 0 to 200 m also corresponded to higher values
of specific ETS, and suggests that higher ingestion rates
occur at night. Enhanced feeding at night has been pre-
viously observed in Antarctic waters. Atkinson et al.
(1996) observed higher grazing rates of copepods, and
Hernández-León, Portillo-Hahnefeld et al. (2001) found
higher gut fullness of Antarctic krill at night. Opposite to

Fig. 3 (a) Day and (b) night averaged vertical profiles (�SD) of biomass (mg protein m-3), specific electron transfer system (ETS) activity
(ml O2 mg protein-1 h-1) and specific aminoacyl-tRNA synthetases (AARS) activity (nm PPi mg protein-1 h-1). Biomass plots show the general vertical
distribution of euphausiids (E), copepods (C) and salps (S).

Antarctic summer zooplankton metabolismL. Yebra et al.

Polar Research 28 2009 415–425 © 2009 The Authors 419



respiration, the specific growth rates (AARS activity)
during the day in the upper 200 m were higher than in the
mesopelagic layer. This indicates higher specific growth
rates in the euphotic zone, where primary production
was concentrated. Also, specific AARS activities did not
increase at night, which suggests that although feeding
seemed to have a day–night cycle, the somatic growth of
the populations remained constant in the upper waters.

Control of zooplankton biomass

One of the main unsolved questions in the region is
which factors determine the low summer zooplankton
biomass. We looked at zooplankton metabolic rates
and food availability to discuss the importance of the
bottom–up and top–down control of zooplankton popu-
lations. The community respiration in the 0–200-m layer
(1.33 mg C m-2 day-1) was similar to the summer 1993
estimates in the Bransfield Strait (1.5 mg C m-2 day-1;
Hernández-León et al. 2000). However, in summer 1994,
the biomass was dominated by salps, and the zooplankton
carbon losses due to respiration ranged from 10 to
50 mg C m-2 day-1 (Alcaraz et al. 1998). On the other
hand, we found that respiration in the mesopelagic
waters (200–550-m depth) was 30% higher than
that in the euphotic zone (2.2 mg C m-2 day-1). When

comparing the average respiration rate of the whole
0–550-m water column (1.74 mg C m-2 day-1) with
the average primary production found in the area
(2854.5 mg C m-2 day-1; Agawin et al. unpubl. data;
Table 2), we observe that the zooplankton daily respira-
tion needs accounted for only 0.06% of phytoplankton
production. This value is much lower than the 0.9
and 5.3% reported for crustacean zooplankton and
salps, respectively, by Alcaraz et al. (1998). Likewise, the
average community ingestion (0–550 m) derived from
respiration represented only 0.15% of the primary pro-
duction. Therefore, in our study, zooplankton metabolic
requirements accounted for less than 0.3% of the photo-
synthetic production. This percentage is lower than that
observed in previous studies (Atkinson & Shreeve 1995;
Lopez & Huntley 1995; Alcaraz et al. 1998; Hernández-
León et al. 1999; Hernández-León et al. 2000).
However, it is important to note that the phytoplan-
kton bloom in February 2000 was notably intense.
The average chlorophyll a concentration varied
from 3.16 � 1.5 mg Chl. a m-3 (ranging from 0.38 to
16.75 mg Chl. a m-3) in open water (Agustí et al. 2004) to
19 � 5 mg Chl. a m-3 within the waters of Deception
Island (Sturz et al. 2003). Also, the primary production
rate was the highest recorded in the area that we know of
(Table 2). The other important food source to consider for

Table 1 Zooplankton biomass (mg protein m-3, except where otherwise noted), specific electron transfer system (ETS; ml O2 mg protein-1 h-1) and
specific aminoacyl-tRNA synthetases (AARS; nm PPi mg protein-1 h-1) activities. Potential respiration (mg C m-2 h-1) and ingestion (mg C m-2 h-1) rates

calculated from specific ETS activities and biomass. Growth rates (nm PPi m-2 h-1) calculated from specific AARS activities and biomass (see Methods) for

depths of 0–200, 200–550 and 0–550 m in the Bransfield Strait.

Depth range

(m)

Day Night

Mean � SD (number of samples) Range Mean � SD (number of samples) Range

Biomass 0–200 0.23 � 0.61 (62) 0.001–4.68 0.54 � 0.39 (21) 0.05–1.56

200–550 0.24 � 0.20 (59) 0.004–0.86 0.25 � 0.32 (28) 0.03–1.71

Average 0–550 0.24 � 0.46 (121) 0.37 � 0.38 (49)

Total 0–550 0.52/130.0* (121) 1.23/179.4* (49)

Specific ETS 0–200 3.12 � 2.03 (76) 0.04–10.86 4.99 � 4.21 (21) 1.05–21.19

200–550 4.23 � 2.69 (83) 0.54–14.18 3.63 � 3.63 (28) 0.51–20.10

Average 0–550 3.70 � 2.45 (159) 4.20 � 3.90 (49)

Specific AARS 0–200 2.49 � 2.28 (62) 0.11–11.36 2.23 � 2.00 (18) 0.03–7.33

200–550 1.26 � 1.70 (65) 0.08–7.87 1.84 � 1.83 (24) 0.07–9.28

Average 0–550 1.86 � 1.90 (127) 2.01 � 1.89 (42)

Potential respiration 0–200 0.037 0.140

200–550 0.092 0.083

Average 0–550 0.065 � 0.039 0.111 � 0.041

Potential ingestion 0–200 0.093 0.350

200–550 0.231 0.206

Average 0–550 0.162 � 0.197 0.278 � 0.102

Growth 0–200 114.54 240.84

200–550 105.84 161.00

Average 0–550 110.19 � 6.15 200.92 � 56.46

* mg protein m-2.

Antarctic summer zooplankton metabolism L. Yebra et al.

Polar Research 28 2009 415–425 © 2009 The Authors420



mesozooplankton is microplankton. E. superba is known
to feed on ciliates as well as copepods (Price et al. 1988;
Froneman et al. 1996; Atkinson & Snyder 1997; Perissi-
notto et al. 2000; Wickham & Berninger 2007). Likewise,
M. gerlachei has shown preference for ciliates and other
copepods over algae, in both austral autumn and winter
(Atkinson 1996, 1998; Pasternak & Schnack-Schiel 2001;
Wickham & Berninger 2007). Calbet et al. (2005) sug-
gested that, in this region, the mesozooplankton was
grazing on microplankton rather than on phytoplankton,
and was therefore aiding the development of the phy-
toplankton bloom. Nevertheless, the net microplankton
production found (76.36 mg C m-3 day-1; Agustí et al.
2004) was much higher than the phytoplankton
production (4.6 mg C m-3 day-1; Agawin, unpubl. data),
although it was similar to the value found in a previous
study in the region (93.35 mg C m-3 day-1; Arístegui et al.
1996). Therefore, the mesozooplankton metabolism
during summer 2000 was not limited by phyto- or
microplankton availability. Hence, as previously sug-
gested (Hernández-León et al. 1999), we reject the
bottom–up control hypothesis.

On the other hand, a top–down effect of krill on cope-
pods has been suggested as the main factor controlling
copepod abundance and development in the Bransfield
Strait (Hernández-León et al. 1999; Hernández-León
et al. 2000; Hernández-León, Portillo-Hahnefeld et al.
2001). This idea is supported by the inverse relationship
of krill/non-krill zooplankton distribution observed here,
and in other Antarctic areas, where high krill densities
coincide with very low copepod abundances (Hosie 1994;
Voronina et al. 1994; Atkinson et al. 1999). As mentioned
above, krill is able to prey selectively on copepods (Price
et al. 1988; Graneli et al. 1993; Atkinson & Snyder 1997),
although their impact on copepods might be reduced in
spring or summer, when phytoplankton concentrations
are high. Hernández-León, Portillo-Hahnefeld et al.
(2001) observed that during the austral summer of 1993
E. superba grazed on phytoplankton by day, but, despite
the high primary production (Basterretxea & Arístegui
1999; Table 2), they switched to feed on M. gerlachei at
night, when copepods migrated upwards. Our study
reflected a similar scenario, with zooplankton biomass in
the lower range and a high primary production. Hence,
the low biomass found could be the result of predation
pressure (top–down control). However, as a result of the
short length of the summer night and the high phy-
toplankton concentrations available to krill during the
bloom, their impact on copepods would be minimal. Thus,
predation might not be the only cause for the low zoop-
lankton biomass in the Bransfield Strait, and copepod life
history might be an important factor to explain the low
values found in summer. Ward et al. (2004) suggested
that the low biomass found was probably linked to
the higher latitude, lower temperatures and reduced
production in comparison with areas further north.
This combination could delay the development of zoo-
plankton populations. This agrees with studies of M.
gerlachei showing that their abundance peaks in autumn,
i.e., March–May (Schnack-Schiel & Hagen 1994, 1995;
Tucker & Burton 1990) or in early winter, i.e., June (King
& LaCasella 2003). King & LaCasella (2003) found the
biomass of M. gerlachei in the waters of Deception Island
(Bransfield Strait) to be 1.7 mg dw m-3 during February
2000, which is similar to the biomass that we observed in
open waters at that time (1.2 mg dw m-3). Nevertheless,
the biomass they found in June (31.4 mg dw m-3) was 20
times greater, showing a four-month lag response of the
copepod population to the phytoplankton bloom. This
may be explained by their preference for microplankton
and small copepods (i.e., Oithona spp.) as prey, the popu-
lations of which would peak after the phytoplankton
bloom. Therefore, it is probable that the low zooplankton
biomass found in summer is not caused by predation
pressure either, but instead is the result of life-cycle

Fig. 4 Day-minus-night averaged value profiles of (a) biomass
(mg protein m-3) and (b) total electron transfer system activity (ETS;

ml O2 m-3 h-1).

Antarctic summer zooplankton metabolismL. Yebra et al.

Polar Research 28 2009 415–425 © 2009 The Authors 421



adaptation of the dominant copepod species to the pro-
duction dynamics in the region.

Vertical migration and carbon fluxes

Biomass in the upper 200-m layer increased by twofold
at night, corresponding to the upward migration of
M. gerlachei (Park & Wormuth 1993; Lopez & Huntley
1995; Hernández-León, Portillo-Hahnefeld et al. 2001;
King & LaCasella 2003). However, the integrated
migrant biomass in the Bransfield Strait was low
(192.0 mg C m-2), compared with previous studies in the
area (Voronina et al. 1994; Hernández-León et al. 2000),
and was within the lower range (20–5200 mg C m-2) of
values found in Antarctica (Boysen-Ennen et al. 1991;
Robins et al. 1995; Ward et al. 1995). The carbon flux
due to migrant fauna respiration below 200-m depth
(10.2 mg C m-2 day-1) represented less than 0.01% of
the averaged primary production measured in the area
(2854.5 mg C m-2 day-1; Agawin, unpubl. data). At the
time of our sampling, Khim et al. (2007) were conduct-
ing a year-long study to determine carbon fluxes to
depths of 960 and 1860 m in the Bransfield Strait. Most
sediment particles (60–73%) were of lithogenic origin,
followed by biogenic silica (20%) and organic carbon
(3–5%). The organic carbon flux was similar at 960- and
1860-m depths (54.98 and 54.49 mg C m-2 day-1, respec-
tively). The authors suggested that this carbon was first
coming from the diatom spring bloom (gravitational
flux), and, later in summer, from zooplankton faecal
pellets (active flux). In this sense, Anadón et al. (2002)
observed summer carbon fluxes in the region ranging
from 160 to 800 mg C m-2 day-1 at depths of 60–65 m.
They calculated an average export flux from the euphotic
zone of 294 � 89 mg C m-2 day-1, which represented
25.6% of the primary production (Varela et al. 2002),
and suggested that the Bransfield Strait played an impor-
tant role as a carbon sink area. On the other hand,
Ebersbach & Trull (2008) observed export fluxes due to

faecal pellets to be 50–60 mg C m-2 d-1 at 100-m depth.
They concluded that the majority of export flux was
processed through the heterotrophic food web, and was
not a direct export of phytoplankton detritus. However,
if that was the case in the Bransfield Strait, carbon
fluxes would be high during autumn and early winter,
when the biomass of copepods peaks. Instead, Khim
et al. (2007) observed that more than 99% of the carbon
flux for the year occurred between December and
February. The extraordinarily minimal fluxes recorded
during the rest of the year suggest important carbon
recycling processes in the absence of phytoplankton
blooms. Nevertheless, Serret et al. (2001) suggested that
seasonal production and respiration uncoupling in the
Bransfield Strait would increase the role of hydrody-
namics (i.e., advection) in the trophic control of carbon
export. Further research during the austral autumn and
winter is needed to reveal the importance of microplank-
ton, both as grazers and as prey, if we seek to assess the
changes in carbon transport to the deep ocean through
the year.

Acknowledgements

We thank the crew of the RV BIO Hespérides, the techni-
cians of the Unidad de Tecnología Marina (CSIC) and the
participants of the ESEPAC 2000 cruise for their support
at sea, especially S. Agustí for inviting us to participate in
the ESEPAC project (ANT97-0273). We are indebted to
N. Agawin for kindly supplying primary production
values obtained during the cruise, and X. Morán and
I.A. Catalán for providing additional data. This work was
undertaken while L. Yebra was at the Biological Ocean-
ography Laboratory of the Universidad de Las Palmas de
Gran Canaria, supported by grants from the Spanish
Science and Education Ministry (MAR97-1036) and the
University of Las Palmas de Gran Canaria. Completion
of this work was funded by the European Social Fund
(I3P programme, CSIC).

Table 2 Interannual variability of mesozooplankton biomass (ZPB; mg C m-2) and average primary production (PP; mg C m-2 day-1) in the Bransfield Strait.

Depth Date ZPB Reference PP Reference

0–200 12/1991 34.6* Hernández-León et al. 1999 333 Basterretxea & Arístegui 1999

0–200 01/1993–02/1993 133.6* Hernández-León et al. 2000 423–3913 Basterretxea & Arístegui 1999

0–200 01/1994 713–1039 Alcaraz et al. 1998 684–1396 Alcaraz et al. 1998

0–200 12/1995–02/1996 136–431 Cabal et al. 2002 14–176 Varela et al. 2002

0–43 02/1998 — — 262–889 Morán et al. 2001

0–200 01/2000–02/2000 94.0–240.5 Present work 578–6911 Agawin unpubl. data

0–550 270.4–373.2

0–200 01/2001–02/2001 9.3–179.3* Catalán et al. 2008 — —

0–250 12/2002 55 Calbet et al. 2005 23–451† Morán et al. 2006

*Carbon calculated from dry weight (dw) applying a C : dw ratio of 0.4 for crustaceans (Postel et al. 2000) and 0.05 for salps (Schneider 1989).
†PP estimated from surface experiments, and assuming 15 h of light per day.

Antarctic summer zooplankton metabolism L. Yebra et al.

Polar Research 28 2009 415–425 © 2009 The Authors422



References

Agustí S., Satta M.P. & Mura M.P. 2004. Summer community
respiration and pelagic metabolism in upper surface
Antarctic waters. Aquatic Microbial Ecology 35, 197–205.

Alcaraz M., Saiz E., Fernández J.A., Trepat I., Figueiras F.,
Calbet A. & Bautista B. 1998. Antarctic zooplankton
metabolism: carbon requirements and ammonium
excretion of salps and crustacean zooplankton in the
vicinity of the Bransfield Strait during January 1994.
Journal of Marine Systems 17, 347–359.

Anadón R., Álvarez-Marques F., Fernández E., Varela M.,
Zapata M., Gasol J.M. & Vaque D. 2002. Vertical biogenic
particle flux during austral summer in the Antarctic
Peninsula area. Deep-Sea Research Part II 49, 883–901.

Arístegui J., Montero M.F., Ballesteros S., Basterretxea G. &
vanLenning K. 1996. Planktonic primary production and
microbial respiration measured by C-14 assimilation
and dissolved oxygen changes in coastal waters of the
Antarctic Peninsula during austral summer: implications
for carbon flux studies. Marine Ecology Progress Series 132,
191–201.

Atkinson A. 1996. Subantarctic copepods in an oceanic, low
chlorophyll environment: ciliate predation, food selectivity
and impact on prey populations. Marine Ecology Progress
Series 130, 85–96.

Atkinson A. 1998. Life cycle strategies of epipelagic copepods
in the Southern Ocean. Journal of Marine Systems 15,
289–311.

Atkinson A., Schnack-Schiel S.B., Ward P. & Marin V. 1997.
Regional differences in the life cycle of Calanoides acutus
(Copepoda: Calanoida) within the Atlantic sector of the
Southern Ocean. Marine Ecology Progress Series 150,
99–111.

Atkinson A. & Shreeve R.S. 1995. Response of the copepod
community to a spring bloom in the Bellingshausen Sea.
Deep-Sea Research Part II 42, 1291–311.

Atkinson A. & Snyder R. 1997. Krill–copepod interactions at
South Georgia, Antarctica, I. Omnivory by Euphausia
superba. Marine Ecology Progress Series 160, 63–76.

Atkinson A., Ward P., Hill A., Brierley A.S. & Cripps G.C.
1999. Krill–copepod interactions at South Georgia,
Antarctica, II. Euphausia superba as a major control on
copepod abundance. Marine Ecology Progress Series 176,
63–79.

Atkinson A., Ward P. & Murphy E.J. 1996. Diel periodicity of
Subantarctic copepods: relationships between vertical
migration, gut fullness and gut evacuation rate. Journal of
Plankton Research 18, 1387–405.

Båmstedt U. 2000. A new method to estimate respiration
rate of biological material based on the reduction of
tetrazolium violet. Journal of Experimental Marine Biology
and Ecology 251, 239–263.

Basterretxea G. & Arístegui J. 1999. Phytoplankton biomass
and production during late austral spring (1991) and
summer (1993) in the Bransfield Strait. Polar Biology 21,
11–22.

Bergeron J.P., Alayse-Danet A.M. & Razouls C. 1985.
Metabolic adaptations of Antarctic mesozooplanktonic
systems to the phytoplankton standing crop in late austral
summer. In J.S. Gray & M.E. Christiansen (eds.): Marine
biology of polar regions and the effect of stress on marine
organisms. Pp. 157–166. Chichester: Wiley.

Boysen-Ennen E., Hagen W., Hubold G. & Piatkowski U.
1991. Zooplankton biomass in the ice-covered Weddell
Sea, Antarctica. Marine Biology 111, 227–235.

Cabal J.A., Álvarez-Marques F., Acuña J.L., Quevedo M.,
Gonzalez-Quiros R., Huskin I., Fernández D., del Valle C.R.
& Anadón R. 2002. Mesozooplankton distribution and
grazing during the productive season in the northwest
Antarctic Peninsula (FRUELA cruises). Deep-Sea Research
Part II 49, 869–882.

Calbet A., Alcaraz M., Atienza D., Broglio E. & Vaque D.
2005. Zooplankton biomass distribution patterns along the
western Antarctic Peninsula (December 2002). Journal of
Plankton Research 27, 1195–1203.

Catalán I.A., Morales-Nin B., Company J.B., Rotllant G.,
Palomera I. & Emelianov M. 2008. Environmental
influences on zooplankton and micronekton distribution
in the Bransfield Strait and adjacent waters. Polar Biology
31, 691–707.

Conover R.J. & Huntley M. 1991. Copepods in ice-covered
seas. Distribution, adaptations to seasonally limited food,
metabolism, growth pattern and life cycle strategies in
polar seas. Journal of Marine Systems 2, 1–41.

Drits A.V., Pasternak A.F. & Kosobokova K.N. 1993. Feeding,
metabolism and body-composition of the Antarctic
copepod Calanus propinquus Brady with special reference to
its life-cycle. Polar Biology 13, 13–21.

Ebersbach F. & Trull T.W. 2008. Sinking particle properties
from polyacrylamide gels during the KErguelen Ocean and
Plateau compared Study (KEOPS): zooplankton control of
carbon export in an area of persistent natural iron inputs
in the Southern Ocean. Limnology and Oceanography 53,
212–224.

Froneman P.W., Pakhomov E.A., Perissinotto R. & McQuaid
C.D. 1996. Role of microplankton in the diet and daily
ration of Antarctic zooplankton species during austral
summer. Marine Ecology Progress Series 143, 15–23.

Gómez M., Torres S. & Hernández-León S. 1996.
Modification of the electron transport system (ETS)
method for routine measurements of respiratory rates of
zooplankton. South African Journal of Marine Science 17,
15–20.

Graneli E., Graneli W., Rabbani M.M., Daugbjerg N., Fransz
G., Cuzinroudy J. & Alder V.A. 1993. The influence of
copepod and krill grazing on the species composition of
phytoplankton communities from the Scotia–Weddell
Sea—an experimental approach. Polar Biology 13,
201–213.

Guerra C. 2006. Growth rate determination in larval krill
(Euphausia superba Dana) during Antarctic autumn in the
Lazarev Sea. A methodology comparison. Master’s thesis,
University of Bremen.

Antarctic summer zooplankton metabolismL. Yebra et al.

Polar Research 28 2009 415–425 © 2009 The Authors 423



Hernández-León S., Almeida C., Portillo-Hahnefeld A.,
Gómez M. & Montero I. 2000. Biomass and potential
feeding, respiration and growth of zooplankton in the
Bransfield Strait (Antarctic Peninsula) during austral
summer. Polar Biology 23, 679–690.

Hernández-León S., Almeida C., Portillo-Hahnefeld A.,
Gómez M., Rodriguez J.M. & Arístegui J. 2001.
Zooplankton biomass and indices of feeding and
metabolism in relation to an upwelling filament off
northwest Africa. Journal of Marine Research 60, 327–346.

Hernández-León S., Almeida C., Portillo-Hahnefeld A.,
Gómez M., Rodriguez J.M. & Arístegui J. 2002.
Zooplankton biomass and indices of feeding and
metabolism in relation to an upwelling filament off
northwest Africa. Journal of Marine Research 60, 327–346.

Hernández-León S. & Gómez M. 1996. Factors affecting the
Respiration/ETS ratio in marine zooplankton. Journal of
Plankton Research 18, 239–255.

Hernández-León S. & Montero I. 2006. Zooplankton biomass
estimated from digitalized images in Antarctic waters: A
calibration exercise. Journal of Geophysical Research—Oceans
111, C05S03.

Hernández-León S., Portillo-Hahnefeld A., Almeida C.,
Bécognée P. & Moreno I. 2001. Diel feeding behaviour of
krill in the Gerlache Strait, Antarctica. Marine Ecology
Progress Series 223, 235–242.

Hernández-León S., Torres S., Gómez M., Montero I. &
Almeida C. 1999. Biomass and metabolism of zooplankton
in the Bransfield Strait (Antarctic Peninsula) during austral
spring. Polar Biology 21, 214–219.

Hosie G.W. 1994. The macrozooplankton communities in the
Prydz Bay region, Antarctica. In S. El-Sayed (ed.): Southern
Ocean ecology. The BIOMASS perspective. Pp. 98–123. London:
Cambridge University Press.

Huntley M.E., Brinton E., Lopez M.D.G., Townsend A. &
Nordhausen W. 1990. RACER: fine-scale and mesoscale
zooplankton studies during the spring bloom, 1989.
Antarctic Journal of the United States 25, 157–159.

Ikeda T. 1985. Metabolic rates of epipelagic marine
zooplankton as a function of body-mass and temperature.
Marine Biology 85, 1–11.

Ikeda T. & Motoda S. 1978. Estimated zooplankton
production and their ammonia excretion in Kuroshio and
adjacent seas. Fishery Bulletin 76, 357–367.

Ikeda T., Torres J.J., Hernandez-Leon S. & Geiger S.P. 2000.
Metabolism. In R.P. Harris et al. (eds.): ICES zooplankton
methodology manual. Pp. 455–532. London: Academic Press.

Jacques G. & Panouse M. 1991. Biomass and composition of
size fractionated phytoplankton in the Weddell–Scotia
confluence area. Polar Biology 11, 315–328.

Khim B.K., Kim D., Shin H.C. & Kim D.Y. 2007. Particle
fluxes and delta N-15 variation of sinking particles in the
central Bransfield Strait (Antarctica). Geosciences Journal 11,
201–209.

King A. & LaCasella E.L. 2003. Seasonal variations in
abundance, diel vertical migration, and population
structure of Metridia gerlachei at Port Foster, Deception

Island, Antarctica. Deep-Sea Research Part II 50,
1753–1763.

Lancraft T.M., Hopkins T.L., Torres J.J. & Donnelly J. 1991.
Oceanic micronektonic macrozooplanktonic community
structure and feeding in ice covered antarctic waters
during the winter (AMERIEZ 1988). Polar Biology 11,
157–167.

Lancraft T.M., Relsenbichler K.R., Robison B.H., Hopkins T.L.
& Torres J.J. 2004. A krill-dominated micronekton and
macrozooplankton community in Croker Passage,
Antarctica with an estimate of fish predation. Deep-Sea
Research Part II 51, 2247–2260.

Lancraft T.M., Torres J.J. & Hopkins T.L. 1989. Micronekton
and macrozooplankton in the open waters near Antarctic
ice edge zones (AMERIEZ-1983 and AMERIEZ-1986).
Polar Biology 9, 225–233.

Lopez M.D.G. & Huntley M.E. 1995. Feeding and diel
vertical migration cycles of Metridia gerlachei (Giesbrecht)
in coastal waters of the Antarctic Peninsula. Polar Biology
15, 21–30.

Lowry P.H., Rosenbrough N.J., Farr A.L. & Randall R.J.
1951. Protein measurement with a Folin phenol reagent.
Journal of Biology and Chemistry 193, 265–275.

Morán X.A.G., Gasol J.M., Pedros-Alio C. & Estrada M.
2001. Dissolved and particulate primary production and
bacterial production in offshore Antarctic waters during
austral summer: coupled or uncoupled? Marine Ecology
Progress Series 222, 25–39.

Morán X.A.G., Sebastian M., Pedros-Alio C. & Estrada M.
2006. Response of Southern Ocean phytoplankton and
bacterioplankton production to short-term experimental
warming. Limnology and Oceanography 51, 1791–1800.

Murray A.W.A., Watkins J.L. & Bone D.G. 1995. A biological
acoustic survey in the marginal ice-edge zone of the
Bellingshausen Sea. Deep-Sea Research Part II 42,
1159–1175.

Omori M. & Ikeda T. 1984. Methods in marine zooplankton
ecology. New York: John Wiley and Sons.

Packard T.T. 1971. The measurement of respiratory electron
transport activity in marine phytoplankton. Journal of
Marine Research 29, 235–244.

Packard T.T., Devol A.H. & King F.D. 1975. Effect of
temperature on the respiratory electron transport system
in marine plankton. Deep-Sea Research 22, 237–249.

Pakhomov E.A., Perissinotto R. & McQuaid C.D. 1994.
Comparative structure of the macrozooplankton/
micronecton communities of the subtropical and
Antarctic Polar fronts. Marine Ecology Progress Series 111,
155–169.

Pakhomov E.A., Perissinoto R. & McQuaid C.D. 1996. Prey
composition and daily rations of myctophid fishes in the
Southern Ocean. Marine Ecology Progress Series 134, 1–14.

Pakhomov E.A., Perissinotto R., McQuaid C.D. & Froneman
P.W. 2000. Zooplankton structure and grazing in the
Atlantic sector of the Southern Ocean in late austral
summer 1993. Part 1. Ecological zonation. Deep-Sea
Research Part I 47, 1663–1686.

Antarctic summer zooplankton metabolism L. Yebra et al.

Polar Research 28 2009 415–425 © 2009 The Authors424



Park C. & Wormuth J.H. 1993. Distribution of Antarctic
zooplankton around Elephant-Island during the austral
summers of 1988, 1989, and 1990. Polar Biology 13,
215–225.

Pasternak A.F. & Schnack-Schiel S.B. 2001. Feeding patterns
of dominant Antarctic copepods: an interplay of diapause,
selectivity, and availability of food. Hydrobiologia 453,
25–36.

Perissinotto R., Gurney L. & Pakhomov E.A. 2000.
Contribution of heterotrophic material to diet and energy
budget of Antarctic krill, Euphausia superba. Marine Biology
136, 129–135.

Postel L., Fock H. & Hagen W. 2000. Biomass and
abundance. In R.P. Harris et al. (eds.): ICES zooplankton
methodology manual. Pp. 83–192. London: Academic Press.

Price H.J., Boyd K.R. & Boyd C.M. 1988. Omnivorous
feeding behaviour of the Antarctic krill Euphausia superba.
Marine Biology 97, 67–77.

Robins D.B., Harris R.P., Bedo A.W., Fernandez E., Fileman
T.W., Harbour D.S. & Head R.N. 1995. The relationship
between suspended particulate material, phytoplankton
and zooplankton duirng the retreat of the marginal ice
zone in the Bellingshausen Sea. Deep-Sea Research Part II
42, 1137–1158.

Rutter W.J. 1967. Protein determinations in embryos. In F.H.
Wilt & N.K. Wessels (eds.): Methods in developmental biology.
Pp. 671–684. New York: Academic Press.

Schalk P.H. 1990. Biological activity in the Antarctic
zooplankton community. Polar Biology 10, 405–411.

Schnack-Schiel S.B. & Hagen W. 1994. Life cycle strategies
and seasonal variations in distribution and population
structure of four dominant calanoid copepod species in the
eastern Weddell Sea, Antarctica. Journal of Plankton
Research 16, 1543–1566.

Schnack-Schiel S.B. & Hagen W. 1995. Life-cycle strategies of
Calanoides acutus, Calanus propinquus, and Metridia gerlachei
(Copepoda: Calanoida) in the eastern Weddell Sea,
Antarctica. ICES Journal of Marine Science 52, 541–548.

Schnack-Schiel S.B. & Mújica A. 1994. The zooplankton of
the Antarctic Peninsula region. In S.Z. El-Sayed (ed.):
Southern Ocean ecology. The BIOMASS perspective. Pp. 79–92.
London: Cambridge University Press.

Schneider G. 1989. Carbon and nitrogen content of marine
zooplankton dry material: a short review. Plankton
Newsletter 12, 41–44.

Serret P., Fernández E., Anadón R. & Varela M. 2001. Journal
of Plankton Research 23, 1345–1360.

Sturz A.A., Gray S.C., Dykes K., King A. & Radtke J. 2003.
Seasonal changes of dissolved nutrients within and around
Port Foster Deception Island, Antarctica. Deep-Sea Research
Part II 50, 1685–1705.

Tucker M.J. & Burton H.R. 1990. Seasonal and spatial
variations in the zooplankton community of an eastern
Antarctic coastal location. Polar Biology 10, 571–579.

Varela M., Fernandez E. & Serret P. 2002. Size-fractionated
phytoplankton biomass and primary production in the
Gerlache and south Bransfield Straits (Antarctic Peninsula)
in austral summer 1995–1996. Deep-Sea Research Part II 49,
749–768.

Voronina N.M., Kosobokova K.N. & Pakhomov E.A. 1994.
Composition and biomass of summer metazoan plankton
in the 0–200 m layer of the Atlantic sector of the
Antarctic. Polar Biology 14, 91–95.

Ward P., Atkinson A., Murray A.W.A., Wood A.G.,
Williams R. & Poulet S.A. 1995. The summer zoplankton
community at South Georgia: biomass, vertical migration
and grazing. Polar Biology 15, 195–208.

Ward P., Atkinson A., Schnack-Schiel S.B. & Murray A.W.A.
1997. Regional variation in the life cycle of Rhincalanus
gigas (Copepoda: Calanoida) in the Atlantic sector of the
Southern Ocean—re-examination of existing data (1928 to
1993). Marine Ecology Progress Series 157, 261–275.

Ward P., Grant S., Brandon M., Siegel V., Sushin V., Loeb V.
& Griffiths H. 2004. Mesozooplankton community
structure in the Scotia Sea during the CCAMLR 2000
Survey: January–February 2000. Deep-Sea Research Part II
51, 1351–1367.

Weeks A.R., Griffiths G., Roe H., Moore G., Robinson I.S.,
Atkinson A. & Shreeve R. 1995. The distribution of
acoustic backscatter from zooplankton compared with
physical structure, phytoplankton and radiance during the
spring bloom in the Bellinghausen Sea. Deep-Sea Research
Part II 42, 997–1019.

Wickham S.A. & Berninger U.G. 2007. Krill larvae, copepods
and the microbial food web: interactions during the
Antarctic fall. Aquatic Microbial Ecology 46, 1–13.

Yebra L., Almeida C. & Hernández-León S. 2005. Vertical
distribution of zooplankton and active flux across an
anticyclonic eddy in the Canary Island waters. Deep-Sea
Research Part I 52, 69–83.

Yebra L., Harris R.P. & Smith T. 2005. Comparison of five
methods for estimating growth of Calanus helgolandicus
later developmental stages (CV-CVI). Marine Biology 147,
1367–1375.

Yebra L. & Hernández-León S. 2004. Aminoacyl-tRNA
synthetases activity as a growth index in zooplankton.
Journal of Plankton Research 26, 351–356.

Yebra L., Hirst A.G. & Hernández-León S. 2006. Assessment
of Calanus finmarchicus growth and dormancy using the
aminoacyl-tRNA synthetases method. Journal of Plankton
Research 28, 1191–1198.

Zhou M., Niller P.P., Zhu Y.W. & Dorland R.D. 2006. The
western boundary current in the Bransfield Strait,
Antarctica. Deep-Sea Research Part I 53, 1244–1252.

Zhou M., Nordhausen W. & Huntley M. 1994. ADCP
measurements of the distribution and abundance of
euphausiids near the Antarctic Peninsula in winter.
Deep-Sea Research Part I 41, 1425–1445.

Antarctic summer zooplankton metabolismL. Yebra et al.

Polar Research 28 2009 415–425 © 2009 The Authors 425