Calanus in North Norwegian fjords and in the Barents 
Sea 
KURT S. TANDE 

K. S. Tande. 1989: Calanus in North Norwegian fjords and in the Barcnts Sea. Pp. 38Y-407 in Sakshaug. 
E.. Hopkins. C. C. E. & 0ritsland. N. A .  (eds.): Proceedings of the Pro Mare Symposium o n  Polar Marine 
Ecology. Trondheim. 12-16 May 1990. Polar Research lo(,?). 

The physical environment of a North Norwegian fjord and of the Atlantic and Arctic domains of the 
Barcnts Sea are described. The seasonal variation of primary production and biomass of thc most important 
copepod species are dcscribed in order to contrast regional differences in the timing of the plankton cyclo. 
Analysis of the seasonal variation in the biomass of six different copepod species in Balsfjordcn clearly 
demonstrate the importance of Calanus finmarchicus as a spring and early summer form, whereas Pseu- 
doculanus acuspes. the most important smaller form. rcachcs the highest biomass later during the productivc 
season. In the Atlantic part of the Barents Sea. C. finmarchicur is the dominant herbivorous form. The 
next most important species, Pseudocalanus sp. and M .  longa. play a less important role here than i n  
Balsfjorden. I n  the Arctic domain, the smaller copepod forms appear to have bccn replaced in tro- 
phodynamic terms by the youngest year-group (C-CHI) of C .  glacialis. which prevails during the Arctic 
summer and autumn periods. The coupling between primary producers and Calmus on a seasonal basis is 
addressed through the grazing and the vertical organisation of the plant-herbivore community. The 
productivity of thcsc two Calanus species is considered in relation to the scasonal and inter-annual variation 
in climate; although different mechanisms are utilised. cold periods tend to lowcr Culunus productivity 
both in the Arctic and the Atlantic domains of the Barents Sea. Interannual variations in Calatrus biomass 
and productivity are discussed in the perspective of endcmic and advective processes. 

Kurt S. Tande. Department of Aquatic Biology. Norwegian College of Fishery Science. University of 
Tromso. N-9001 Tromsm, Norwuy 

Introduction 
The ecology of the North Atlantic has been inten- 
sively studied for several decades. The majority 
of the studies have concentrated on the eastern 
region, with most effort probably concentrated 
on the North Sea, the Norwegian Sea, and the 
adjacent continental shelf. The Norwegian 
Atlantic current transports Atlantic Water north- 
eastwards, thereby creating a marine environ- 
mental continuum which extends to the Barents 
Sea and further northwards to the western coast 
of Svalbard (Blindheim & Loeng 1981). With 
these fairly homogeneous physical environmental 
conditions we would expect to find a plankton 
community which is structured and functions basi- 
cally in the same way throughout the entire area. 
In this study the physical environments of a North 
Norwegian fjord and the Atlantic and Arctic 
domains in the Barents Sea are described. The 
seasonal variation of primary production and bio- 
mass of the most important copepod species are 
also described in order to contrast any regional 

differences in the timing of the plankton cycles. 
Species succession in the phytoplankton and cope- 
pod communities is described in order to charac- 
terise differences among the pelagic communities 
from neritic coastal waters in northern Norway, 
the Atlantic waters of the Barents Sea, and the 
Arctic portion of the Barents Sea. 

The species composition and seasonal growth 
cycles of herbivorous copepods have been 
described in the Norwegian fjords by Hopkins et 
al. (1984,1985). The most abundant herbivorous 
copepod species belong to the genus Calanus, and 
Calanus finmarchicus should be considered the 
key species throughout the area of Atlantic waters 
(Matthews 1967; Jaschnov 1970, 1972). The geo- 
graphical range of C. hyperboreus and C. glacialis 
is related to different water masses which link the 
former to deep water masses in the Norwegian 
Sea and to Arctic waters in the Northern Hemi- 
sphere (Jaschnov 1967). The only true Arctic 
species, C. glacialis, is consistently present in 
waters north of the Polar Front. This paper pre- 
sents data for seasonal biomass cycles of the most 
important copepods in the region, with special 



390 K .  S. Tande 

A 7 0" 

Fig. 1. Surface currents in the Norwegian 
Sea. the Barents Sea. and in coastal 
waters of northern Norway (A); 
topography in fjords around Tromse ( B )  
and in the Barents Sea (C). Broken 
line = mean position of the Polar Front. 

sd 

7 5( 

7 0' 

emphasis on C. finniarchicirs and C. glacialis in 
the Barents Sea ecosystem. Climatic changes 
could modify the productivity of these two 
species. I attempt t o  explain the biological basis 
behind such a possible modification. T h e  tropho- 
dynamic role of Calanus and the vertical organ- 
isation of the plant-herbivore relationship are 
discussed. based o n  data obtained mainly during 
the Pro Mare programme. 

The physical environment 
The seasonal and interannual variations in the 

physical environment in coastal waters of north- 
ern Norway and in the Barents Sea are to a large 
extent driven by processes in the oceanic North 
Atlantic (Cushing & Dixon 1976). The North 
Atlantic Current enters the Norwegian Sea mainly 
through the Faroe-Shetland Channel. Before it 
reaches the Norwegian continental shelf between 
62 and 63"N, a branch diverts into t h e  North Sea 
along the western and southern slopes of t h e  
Norwegian Channel (Blindheim & Loeng 1981). 
The bulk of the Atlantic W a t e r  flows northwards 
and splits in two branches off the coast of Troms, 
in northern Norway. O n e  branch continues north- 
wards as the West Spitsbergen C u r r e n t ,  and the 



Calanus in North Norwegian fjords and in the Barents Sea 391 

other is diverted into the Barents Sea as the North 
Cape Current. 

North Norwegian f o r d s  

The Atlantic Water is, to a certain extent, isolated 
from the coast of Norway by the Norwegian 
Coastal Current. Freshwater from the Baltic Cur- 
rent mixes with North Sea and Atlantic waters to 
form the northward flowing Norwegian Coastal 
Current. Light coastal water spreads out in a 
wedge form above the heavier Atlantic Water. 
The seaward extent of this wedge of coastal water 
varies seasonally and reaches its maximum in 
winter. Along the Norwegian coast there is a 
further supply of freshwater runoff, but in spite 
of this there is an increase in salinity towards the 
north which is due t o  mixing with Atlantic Water. 

Although Balsfjorden (69"N; 19"E) is generally 
a cold fjord, the physical environment is con- 
sidered to be representative of North Norwegian 
fjords (Fig. 1). The general topography, seasonal 
temperature variation, salinity, and stability are 
described in Eilertsen et al. (1981). These fjords 
have from one to several basins with a maximum 
depth of ca. 200 m. The temperature varies from 
about 1 to 7"C, and the salinity ranges from ca. 
32.80 to 34.00 during most of the year. 

Barents Sea 

The Coastal Current enters the southeastern 
region of the Barents Sea. The southern part of 
the Atlantic Current continues eastward together 
with the Norwegian Coastal Current and proceeds 
along the Murman coast as the Murman Current 
(Midttun & Loeng 1987). A northern part (North 
Cape Current) transports Atlantic Water into the 
Barents Sea along the channel, Bjorn~yrenna. 
The influx of Arctic Water to the Barents Sea 
takes place along two main openings between 
Frans Josef Land and Novaja Zemlja (Dickson et 
al. 1970). The area where the Atlantic and the 
Arctic water masses meet is called the Polar 
Front. In the area west of Sentralbanken, the 
Polar Front is sharp and shows features typical of 
the bottom topography. In the eastern Barents 
Sea, the frontal area is less distinct, and mixed 
water masses cover large areas (c.f. Fig. 1). 

Atlantic water masses are, in general, defined 
by salinities of >35.00 (Helland-Hansen & Nan- 
sen 1909). At the entrance to the Barents Sea, 
the mean salinity and temperature in the core 

during the period 1967-1977 were 35.13 and 
6.2"C, respectively (Blindheim & Loeng 1981). 
Further east, the characteristic change t o  lower 
salinity and temperature has been demonstrated 
by Loeng & Midttun (1984). Arctic Water, or the 
Barents Sea Winter Water, is mainly found in 
the intermediate layer (from 20 to 150 m) in the 
northern Barents Sea. The core is usually found 
between depths of 30-60m with a temperature 
below -1.5"C and a salinity between 34.4 and 
34.6 (Midttun & Loeng 1987). 

Seasonal variations in the position of the ice 
border are, in general, similar from year to year 
with maximum and minimum extension in March- 
May and August-September (Loeng & Vinje 
1979). Ice formation usually starts in late Sep- 
tember or October, and the ice border moves 
rapidly southwards to the Polar Front during Nov- 
ember and December. The retreat of the ice starts 
in May. In the beginning, the rate of melting is 
slow, but it increases and reaches its maximum in 
July and early August. Considerable interannual 
variations in sea ice extension occur and variations 
within the extremes can exceed 500 km, especially 
in summer and autumn. Large variations in the 
temperature of the Atlantic waters have been 
observed which indicate variability in the inflow 
and/or cooling of these water masses (Adlandsvik 
1989). A more comprehensive description of the 
physical environment in the Barents sea is given 
in Loeng (1991 this volume). 

The biological environment 
Primary production 

In Balsfjorden, in northern Norway, the light 
regime varies considerably on a seasonal basis, 
with negligible or immeasurable light in Decem- 
ber and January (Eilertsen & Taasen 1984). The 
sun stays below the horizon from 26 November 
until 18 January and is continuously above the 
horizon during the period of midnight sun from 
28 May to 19 July. At the end of March mean 
daily radiation is more than 200 ly d-l until the 
end of August. The primary production period 
starts in March, reaching a maximum of ca. 
650mg C d-' in mid-April, followed by a cul- 
mination period in May (Eilertsen & Taasen 
1984). A subsidiary peak in production, although 
not necessarily a yearly phenomenon, occurs dur- 
ing August and September through stability 



392 K .  S .  Tande 

deformation in surface waters (Eilertsen 1983: 
Eilertsen & Taasen 1984). Integrated annual pri- 
mary production for the years 197&1978 is ca. 
120 g C m-:. 

In the Barents Sea, physical conditions may b e  
very different from o n e  area to a n o t h e r ,  mainly 
because ice tends t o  reduce atmospheric influ- 
ences on the water masses. Additional variability 
is enforced by bottom topography, currents. and 
differences in the physical conditions of the sea- 
water. Spring phytoplankton blooms are the 
result of light intensity at a particular depth and 
the rate of vertical mixing of the water column 
Water column stabilisation is necessary for the 
onset and development of any high latitude spring 
bloom (Sverdrup 1953; Sambrotto e t  al. 1986). 

Two different sets of conditions. although not 
mandatory for the onset of the spring bloom. 
could exist during spring in t h e  Barents Sea. First, 
when the ice extends t o  the south of the Polar 
Front. Atlantic Water could initiate the melting 
of ice early in the spring, d u e  to its relatively high 
water temperatures. This would, in principle, 
have the same effect as the melting period d u e  t o  
increased solar radiation which would normally 
take place at a later period in t r u e  Arctic Water. 
Such melting enhances stability, and favours an 
intense spring phytoplankton bloom (see Fig. 7 )  
Second, the oceanic waters not influenced by ice 
formation are most frequently found in the Atlan- 
tic domain. T h e  yearly build-up of the ther- 
mocline in these waters takes place in J u n e ,  
generally with low stability of t h e  water masses 
throughout April and May (Skjoldal e t  al. 1987). 
This would tend t o  shift the culmination of the 
phytoplankton bloom towards the end of May 
and the beginning of J u n e ,  although a substantial 
primary production has taken place during April 
and May. Using model simulations. the annual 
primary production has been estimated t o  be ca. 
70 g C m-? y r - '  and 55 g C m-' y r - '  in the Atlan- 
tic and Arctic domains, respectively (Slagstad & 
Tande 1990: Tande & Slagstad 1991) 

Information from field investigations in the 
Barents Sea indicates that the spring phy- 
toplankton bloom is initiated in April in unstrati- 
fied Atlantic water masses (Skjoldal et al. 1987; 
Eilertsen et al. 1989). In the fjords of the western 
coast of Svalbard, a t  a latitude of 8-10' further 
north, the spring bloom was shown t o  start at 
approximately the same time as the spring bloom 
in the coastal areas of northern Norway (Eilertsen 
et al. 1989). It is noteworthy that the spring bloom 

in the Balsfjorden area and in t h e  Atlantic Water 
of the Barents Sea occurs in unstratified water 
masses. This means that t h e  rate of vertical mixing 
in these areas allows for net phytoplankton pro- 
duction before any of the conventional physical 
criteria show any density gradient. Eilertsen e t  al. 
(1989) draw attention t o  the fact that after t h e  
vernal equinox (21 March) the day-length 
increases at a faster rate at high latitudes, and 
that this rapid increase in day-length enhances 
primary production when compared t o  areas 
further south. They conclude that the critical 
depth is deeper in northern areas, since the days 
are longer further north and the global radiation 
values are comparable between, for instance, 70 
and 78"N from March to May. T h u s ,  stratification 
of the water masses in t h e  Barents Sea tends t o  
fix the time of culmination rather than t h e  onset 
of the spring phytoplankton bloom in t h e  Atlantic 
Water of the Barents Sea. 

Composition of phytoplankton species 

In fjord areas in northern Norway flagellates of 
size <5 pm prevail regularly during t h e  pre-bloom 
period in March (Eilertsen pers. commun.), 
whereas the diatoms Chaetoceros socialis, Nitz- 
schia grunowii, Thalassiosira gravidalrotula, T .  
nordenskioeldii, and the prymnesiophyte, Phae- 
ocvstis pouchetii, constituted the bloom in April 
and May. T h e  proportion of diatoms and P .  p o u -  
chetii in the phytoplankton during t h e  spring 
bloom shows a shift toward a predominance of P .  
pouchetii during May a n d  J u n e  (Eilertsen e t  al. 
1981; Eilertsen & Taasen 1984). During t h e  
autumn. small amounts of P. pouchetii were 
present together with t h e  coccolithophorides 
Anthosphera robusta and Emiliania huxley, as 
well as small amounts of diatoms and dino- 
flagellates. 

D a t a  from Trondheimsfjorden (63"N) in the 
south t o  Ullsfjorden (69") in the north show that 
the species Chaeotoceros socialis, Phaeocystis 
pouchetii, and Skeletonema costaturn a r e  common 
components of t h e  spring phytoplankton in five 
different localities along t h e  coast ( G a a r d e r  1938; 
Sakshaug 1972: H e i m d a l l 9 7 4 ;  Schei 1974; Eilert- 
sen et al. 1981). Eilertsen e t  al. (1981) attribute 
this similarity among t h e  dominant species t o  t h e  
estuarine circulation which prevails between the 
fjords and the Norwegian Coastal Current. 

A correspondingly detailed description of the 
seasonal succession in phytoplankton species 



Calanus in North Norwegian fiords and in the Barents Sea 393 

composition in the Atlantic and Arctic waters 
of the Barents Sea is unavailable. Nevertheless, 
diatoms of the genera Chaetoceros, Thalassiosira, 
and Nitzschia, and the prymnesiophyte Phae- 
oecystis pouchetii, are the most important species 
in these waters. The species succession during the 
spring and early summer period tend to show 
the same pattern as found in coastal waters in 
northern Norway (Eilertsen pers. comm.). 
Blooms associated with the ice edge tend to be 
characterised by slightly different floral assem- 
blages, both in Atlantic and Arctic waters. The 
under-ice phytoplankton species Melosira arctica, 
Thalassiosira bioculata, and Actinocyclus sp. pre- 
vail in multi- and two-year-old ice, whereas the 
pennate diatoms Navicula vanhoeffeni and Nitz- 
chia frigida are found primarily under one-year- 
oldice (Nost-Hegseth, pers. commun.). Although 
blooms of these species are associated with the 
under ice surface, Thalassiosira spp. can be found 
as important members during the spring bloom in 
pelagic waters during the retreat of the ice edge. 

Regional differences in the 
copepod community 
In Balsfjorden, in northern Norway, the total 
copepod biomass in 1977 was in general low dur- 
ing winter and spring, and the maximum appeared 
late in the summer (Fig. 2). Compared to more 
oceanic environments, for example the ocean 
weather station I (OSW I )  in the North Atlantic, 
a two-fold higher annual primary production in 
Balsfjorden translates into higher overall standing 

BALSFJORDEN 
- - l o o r  0-0 PRIMARY PRODUCTION 1 6 0  

stocks of copepods, with mean monthly averages 
of 24mg wet weight m-) at OSW I (Parsons & 
Lalli 1988, fig. 7) and 18mg dry weight m - j  in 
Balsfjorden (Fig. 2). Primary production and 
copepod production, reflected in biomass build- 
up, appears to be more closely coupled in the 
North Atlantic than in Balsfjorden. Peaks in phy- 
toplankton production and zooplankton biomass 
at OSW I were in June, while in Balsfjorden the 
peaks were in April and in the autumn. This is, 
in general, considered to be a combined effect of 
differences in temperature, species composition. 
and life cycle patterns of the species involved in 
these two environments. 

Detailed descriptions of the zooplankton com- 
munity in Balsfjorden, based on data obtained 
during the second half of the 1970s, have been 
given by Tande (1982) and Hopkins et al. (1984). 
Six different copepod species occur regularly 
throughout the year in this fjord (Fig. 3). Among 
the smaller forms are the calanoid Microcafanus 
pusillus and the cyclopoid Oithona sirnilis. Species 
of intermediate size (adult size < 1.5 mm in pro- 
some length) are Acartia longiremis and Pseu- 
docalanus acuspes. Metridia longa and Calanus 
finmarchicus are the larger copepods in the fjord. 
Occasionally, C .  hyperboreus, Ternora longi- 
cornis, and Euchaeta norvegica are recorded in 
the fjord and are possibly associated with the 
inflow of oceanic waters in the coastal current. 
Population data were obtained from Balsfjorden 
for M. longa via sampling once or twice a month 
during 1978 (Granvik & Hopkins 1984) and 
monthly for all the other species during 1977. 

10 

Fig. 3. Seasonal variation in biomass for the copepods Calanus 
finmarchicus (CFIN). Merridia longa ( M E T ) .  t'seudocalanus 
acuspes (PSEU). Acarria longeremis ( A C A R ) ,  Oirhono sitnilis 
(OITH), and Microcalanus pusillus (MICR) in Balsfjorden. 

TIME 

Fig. 2. Seasonal variation in primary production and copepod 
biomassin Balsfjorden, northern Norway, in 1977. The primary 
production data are adopted from Eilertsen & Taasen (1984). 



394 K. S. Tande 

Copepod biomass 

Calculations of the biomass are based on dry 
weight data from various sources. Adult dry 
weights of Microcalanus pusillus of 5.7 yg and a 
mean dry weight of 1.6 yg for CI-CV are cal- 
culated from data given in Davis (1984). assuming 
40% of the dry weight as carbon content. The 
cyclopoid copepod Oithona similis is converted 
to biomass by assuming a mean dry weight of 1 yg 
(CIV) and 2.2 ygforcopepodite stages and adults, 
respectively. Data for adults are given by Evans 
(1977), and the dry weight for CIV is calculated 
assuming a 50%) weight increment per stage (see 
McLaren et al. 1989). Adult dry weights of 6 yg 
have been obtained for Acartia longiremis from 
waters around T r o m s ~  (Norrbin et al. 1990). Car- 
bon contents for copepodite stages are given by 
Berggreen et al. (1988) and have been converted 
to dry weights assuming a dry weight carbon 
content of 40%. Taking a dry weight of 10 pg for 
CV and adult Pseudocalanus acuspes (Norrbin et 
al. 1990), dry weights for the other copepodite 
stages were calculated using a weight increment 
of 50% per stage (see Davis 1984; Klein Breteler 
et al. 1982). The seasonal variation in dry weights 
and CIV, CV, and adult Calanus finmarchicus, 
and of CV and adult Metridia longa are given i n  
Tande (1982) and Grenvik & Hopkins (1984). 
For CI-CHI C.finmarchicus, dry weights obtained 
i n  t h e  Barents Sea were adopted in the present 
calculation (Tande & Slagstad 1991). For cope- 
podite Stages I-IV of M .  longa, the dry weights 
have been calculated by converting the dry 
weights from corresponding stages of C .  fin- 
marchicus using a dry weight factor (0.4) between 
CV and adult females obtained from these two 
species in Balsfjorden (Tande 1982). 

Minimum standing stocks in terms of dry weight 
were found during the winter for all of the species 
listed. The most dramatic changes were found in 
Acartia longiremis, which was virtually absent 
during the overwintering period (Fig. 3). A dra- 
matic decline in C. finmarchicus stock is associ- 
ated with the period of reproduction in March 
and April. The two more herbivorous species. C .  
finmarchicus and P. acuspes, rely to a greater 
extent on wax esters during the winter period 
(Norrbin et al. 1990) and commence spawning at 
the beginning of the spring bloom at the end of 
March (Die1 & Tande 1991). The more omnivor- 
ous copepod species. Metridia longa, for which 
the intake of energy is essential during the winter 

season, spawns at the end of the spring bloom 
in May (Tande & Grenvik 1983), whereas the 
increase in the biomass of A .  longiremis in May 
and June is probably due more to the hatching of 
resting eggs produced the year before (Pertzova 
1974; Lindley 1990). 

Clearly C .  finmarchicus dominates during 
spring and early summer, whereas the smaller 
form, P. acuspes, reaches the highest biomass 
later in the productive season (Fig. 3). Although 
the variation in the biomass during the season 
could be partly due to advection into the fjord, 
the general picture of a separation in time 
between these two species is expected according 
to the generation pattern. The annual generation 
of C .  finmarchicus produced from April to June 
shows an increase in production at the subsidiary 
peak in primary production during August and 
September which is usually found in these waters 
(Tande 1982). P .  acuspes is represented by two or 
possibly three generations in this fjord (Norrbin 
1987), giving rise to a build up in biomass in late 
summer and autumn (Fig. 3). 

A corresponding list of copepod species can be 
constructed for both the Atlantic and the Arctic 
domains in the Barents Sea. Based on abundances 

-- 

w MET 
MlCR 

72 73 7 4  75 75.5 76 77 7a 79 
LATITUDE (" N) 

ATLANTIC ARCTIC - - 
POLAR FRONT 

Fig. 4 Rcgional variations in biomass of the most quantitative 
important copcpods during the summer and autumn of 19x1 in 
thc Barenls Sea. Symbols as in Fig. 3 .  Rcdrawn from Ilassel 
( 1 YR6). 



Calanus in North Norwegian fiords and in the Barents Sea 395 

published by Hassel(l986), biomasses have been 
calculated for the numerically most important 
copepods in the Arctic and Atlantic domains dur- 
ing the summer of 1981 (Fig. 4). Data were selec- 
ted from two cruises on a transect covering 
73”OO’N t o  75’59” and 75’30” t o  78”50‘N, from 
27-28 June and 8-10 August, respectively (see 
Fig. 1). An abundance of data was converted to 
biomass data using the same stage-specific dry 
weights given above. The abundance of Calanus 
was not separated at the species level in the inves- 
tigation, but Hassel(l986) found that the majority 
of Calanus spp. to the north of the Polar Front 
belonged to C. glacialis, whereas C. finmarchicus 
prevailed in Atlantic waters. In order to empha- 
sise the differences in the copepod community 
across the Polar Front, the abundance of Calanus 
spp. given in June and August 1981 has conse- 
quently been converted to biomass data. This was 
done by adopting dry weights of C. finmarchicus 
and C. glacialis for the cruises in June and August, 
respectively. At 76”N where the two lags over- 
lapped, the biomass of Calanus is given as the 
sum of the biomass calculated in June as C .  fin- 
marchicus and in August as C. glacialis. Dry 
weights for C. glacialis (copepodite stages and 
adults) and for C. finmarchicus are based on data 
from Slagstad & Tande (1990) and Tande & Slag- 
stad (1991), respectively. 

The largest copepodite stages and adults of C. 
glacialis were not quantitatively sampled by a 
36-cm diameter Juday net with 180pm mesh. 
Nevertheless, the overall changes in the pro- 
portion of the biomass between the species mir- 
rors important differences in the copepod 
community across the Polar Front in the Barents 
Sea. Compared to Balsfjorden, however, there 
are definite changes in the proportions and the 
potential quantitative importance among the 
species. In general terms, C. finmarchicus appears 
to have attained a more central position in Atlan- 
tic waters than in the coastal areas in northern 
Norway, with biomasses of ca. 70 mg dw rne3 at 
73”N in June. A reduced quantitative importance 
of the smaller copepod forms is also apparent, 
especially in the Arctic Water. The biomass of the 
Arctic species C. glacialis increases at increasing 
distances from the Polar Front, attaining a maxi- 
mum of ca. 30mg dw m-3 at 79’”. From the 
current data these two Calanus species appear in 
low biomasses in the region of the Polar Front, 
but further data analysis and investigations are 
required to substantiate this pattern. 

The transect in August coincides with the end 
of the productive period, both in the most north- 
ernmost areas in the Atlantic domain and in true 
Arctic Water at 79”N. The more neritic species, 
such as Acartia longiremis, are recorded only 
occasionally in the Barents Sea (Norrbin pers. 
commun.) and are of minor quantitative import- 
ance. The other copepod species, Microcalanus 
pusillus, Oithona similis, Pseudocalanus spp. and 
Metridia longa, are found in lower biomasses in 
the Barents Sea as compared to Balsfjorden dur- 
ing the autumn. The two latter forms are listed 
as the most abundant copepods next to Calanus 
in the Barents Sea (Skjoldal et al. 1987), but the 
data from 1981 indicate that both Pseudoca1anu.s 
spp. and M .  longa play a less important tro- 
phodynamic role in the Barents Sea ecosystem 
compared to Balsfjorden. The biomass data show 
a maximum of Pseudocalanus spp. and 0. similis 
in the Polar Front region, reflecting the annual 
build-up of these populations in Atlantic waters 
analogous to that found in Balsfjorden during the 
autumn. A large abundance of CI-CIII shows that 
M .  longa would also have an equivalent potential 
(Hassel 1986), but this is not seen in the biomass 
build-up which is anticipated to take place later 
in the autumn when CIV, CV, and adults appear 
in the population (see Tande & Granvik 1983). 
The smallest copepod species, M .  pusillus, 
increases in biomass at increasing distance to the 
north of the Polar Front. Although biomass values 
are low, the species should be considered impor- 
tant in trophodynamic terms due to its numerical 
dominance in the Arctic waters of the Barents 
Sea. 

Culunus: species distribution in the 
Barents Sea 
The three species in the genus Calanus occur 
regularly in the Barents Sea. Although C. f i n -  
marchicus is considered to be Atlantic, it gen- 
erally occurs near the Polar Front (Fig. 5). Depth- 
integrated biomasses (0-100 m) of adult female 
C. finmarchicus and C .  glacialis given as means 
from four different stations obtained during a 
cruise with R. V .  ANDENES 19 and 20 April 1986 
in the same region revealed that the standing 
stock of adults was 132 and 96 mg C m-*, respect- 
ively. Maturity analyses (unpubl. data) confirm 
that both species had already started spawning in 
this region as early as mid-April. This is consistent 



396 K. S. Tande 

80 

7 5  

7c 

80 

7 5  

7 3  

20" 30" 40" 

17-23 JULY 1987 '"\ I 

70" 

20" 30' 40" 

20' 30' 40' 

Fig. 5 .  Dcpth intcgratcd biomass (0-100 m) for three species 
in the genus Culaiiiis. C. finmarchicus. C. ,yluciulis and C. 
h,vprrhoreirs. 'from three periods in 1986 (A). 1987 ( B ) .  
and lYX1 ( C ) .  



Calanus in North Norwegian fjords and in the Barents Sea 397 

with observations for C .  glacialis from the Fram 
Strait which showed pre bloom spawning at 
chlorophyll concentrations <0.1 mg m-3 at the 
end of March (Smith 1990). 

In July 1987, although the CIV and CV dom- 
inated the biomass (Fig. 5B), CI-CIII was clearly 
the most abundant stages (see Hansen et al. 1990). 
Using depth-integrated carbon from the surface 
to 100 m, the biomass data were calculated from 
abundance data and stage specific carbon content 
for C .  hyperboreus, C .  finmarchicus and C .  gla- 
cialis as given in Hansen et al. (1990), Slagstad 
& Tande (1990), and Tande & Slagstad (1991), 
respectively. The size frequency distributions of 
the CI-CIII copepodites did not show any clear 
species separation (see also Hansen et al. 1990, 
fig. 2). However, in C .  glacialis CIV-adults pre- 
vailed both in abundance and biomass at Stations 
1 and 3, while C. finmarchicus was found with the 
highest biomass at Station 2. At this time, C .  
hyperboreus was present as CIV, CV, and adult 
females at biomass <75 mg C m-* in these waters. 

In Arctic waters at 77 and 82"N (Fig. 5C), C. 
glacialis prevailed, supporting the idea that this 
is a true Arctic species (Jaschnov 1972; Tande et 
al. 1985). Depth-integrated biomass from depths 
of 20 to 80 m have been obtained from an inves- 
tigation conducted on 25 July (Station 1) and 27- 
28 July (Station 2) by R. V. LANCE in 1984. The 
investigation is described in detail in Eilertsen et 
al. (1989). Due to high abundances of CI-CIII at 
both stations, the biomass of these stages 
exceeded the sum of the other copepodite stages 
and adults. Although CI-CIII were present for 
C .  hyperboreus, the majority of biomass in this 
species was found as CIV, CV, and adult females. 
At Stations 1 and 2 this species was found with 
biomasses of 764 and 1297mg C m-2, respect- 
ively, which are probably underestimates but sub- 
stantially above the values described for the Polar 
Front (Fig. 5A and B). 

The data indicate that the importance of C .  
hyperboreus in terms of biomass appears to 
increase with latitude in the Barents Sea, at least 
in certain years and regions. Data from the Fram 
Strait indicate also that the species is found at 
higher biomasses in Arctic Water than in Atlantic 
Water (Barthell988; Diel 1989). This has, among 
other things, led to the theory that this species is 
Arctic (Conover 1988). However, the high bio- 
masses generally found in the Arctic could equally 
well reflect low predation rates and hence 
increased longevity as compared to the Atlantic. 

The species is widely distributed and commonly 
found, although not reproducing, on the western 
coast of Norway (Matthews et al. 1978). This 
emphasises that C .  hyperboreus is the most 
cosmopolitan of the three species in the Calanlts 
complex, with an Atlantic population base depen- 
dent on deep waters for maintaining a successful 
life cycle. 

The other two species of Calanus occupy the 
two different domains i n  the Barents Sea which 
coexist in the Polar Front region. The interchange 
of these two species north of the Polar Front 
depends on the rate of exchange of Atlantic and 
Arctic waters and on the balance between recruit- 
ment and mortality in the two populations. From 
what has been outlined above, I will in the fol- 
lowing describe how C .  finmarchicus and C .  gla- 
cialis function in trophodynamic terms in the 
Atlantic and Arctic regions, respectively. The 
objective will be to delineate how climatic changes 
in the region could alter the potential productivity 
of these two species and thereby influence the 
rate of energy flow within the pelagic food web 
in the Barents Sea. 

Calanus glacialis 
Generation pattern and biomass 

Although a two year generation cycle has been 
suggested for Calanus glacialis in the Barents Sea 
(Prygunkova 1968; Naumenko 1979; Tande et al. 
1985; Slagstad & Tande 1990), an annual life cycle 
has been suggested for populations off south- 
western Nova Scotia (Runge et al. 1986), for 
the inner Godthlb fjord (MacLellan 1967), Fram 
Strait (Smith 1990), and for the Davis Strait 
(Huntley et al. 1983). The presence of CI-CIII 
C .  glacialis during the productive season, with 
notable maximum abundances from mid-June to 
mid-August, is a consistent feature in the Arctic 
(Grainger 1961; MacLellan 1967; Diel 1989; 
Eilertsen et al. 1989; Hansen et al. 1990). A 
flexible spawning behaviour pattern for C. gla- 
cialis is attained by long-term preservation of 
its reproductive potential, rapid mobilisation of 
ovaries during periods of favorable food 
conditions, and high rates of egg production (Hir- 
che & Bohrer 1987; Hirche 1989). Although C. 
glacialis has been considered to spawn during the 
Arctic spring bloom, Smith (1990) showed that 
food was not required for spawning in the Fram 



398 K .  S .  Tande 

Strait in late March and early April. Cohorts 
produced during spawning in April would favour 
a generation time of o n e  year, although spawning 
in May and June would be more suitable for 
a two-year life span (Slagstad & T a n d e  1990). 
Spawning, and the subsequent development of 
recruits in August and September, allows a fairly 
low chance of building u p  energy reserves for 
survival through the overwintering period; these 
recruits are likely to be considered as pseu- 
docohorts (see Hirche 1989). C a r e  should be 
taken when estimating the length of the life cycle 
based on embryonic development and the pos- 
tulated rule of equiproportional development (see 
Corkett e t  al. 1986; T a n d e  1988a; Smith 1990; 
Pedersen & Tande 1991). However, the lack of 
frequent sampling o n  a seasonal basis of C .  gla- 
cialis restricts o u r  chances of tracing the periods 
of diapause, which should give two major over- 
wintering stages (CIV and C V )  in a two-year 
life cycle. Although the available data give n o  
conclusive evidence for either an annual or a 
biennal life cycle, it could well be that the above 
reports mirror a flexible life cycle, where the 
circulation pattern. the extent of the productive 
period. and the timing of spawning determine the 
fraction of the population which enter a two-year 
life cycle. 

A generally higher standing stock, without the 
extremely low winter biomass which is found for 
species with an annual life cycle, would be antici- 
pated for a species with a two-year life cycle such 
as C. glacialis. This is clearly demonstrated in the 
data from the central Arctic Ocean where the 
total biomass of C. glacialis from three different 
depth strata showed very low seasonal variation 
during an investigation from January t o  Decem- 
ber (Brodsky & Nitikin 1955; Grainger 1989). 
Slagstad & Tande (1990) presented model simu- 
lations of C. glacialis based o n  maximum popu- 
lation abundances in Arctic Water of the Barents 
Sea which yielded biomass estimates of approxi- 
mately 5 g C m-: for August (Fig. 6). as compared 
to a maximum of 4 g C m-' for the total copepod 
community in Balsfjorden. T h e  simulated values 
should be considered as maximum values since 
conservative estimates of 3.2 and 2 . 9 g  C-' are 
found for C. glacialis in Arctic Water east of 
Svalbard at the end of July 1984 (see Fig. 5 C ) .  
Considerable regional variations in the popu- 
lation density of C. glacialis are found. where 
notably lower biomasses (2.15, 1.35 and 0.29 g C 
m-' at Stations 1. 2. and 3. respectively) are 

Calanus glacialis 
I 

I J I I ~  1 1 1 1  
May ' Jun ' Jul ' Aug ' Sept 

TIME 

Fig. 6. Simulated standing stock of two year groups of Calanus 
glucialk (adult females/CIV/CV and CI-CIV. respectively) 
from May to September in the Barcnts Sea. The population 
dynamics in the model are based on a two year life cycle. See 
Slagstad & Tandc ( 1 9 Y O )  for further details. 

recorded in the Polar Front in July 1987 (Fig. 
SB). An even lower biomass (0.14g C m-') was 
obtained in April 1986 in the same region (Fig. 
5A). Compared t o  Atlantic Water in the Barents 
Sea, there is a tendency in t h e  Arctic domain 
for a reduction in the quantitative importance of 
smaller copepods such as Pseudocalanics s p ,  and 
Oithona similis (Hassel 1986), which normally 
reach maximum biomass during late summer and 
autumn in Atlantic Water. These species appear 
to have been replaced in trophodynamic terms by 
the youngest year-group (CI-CHI) of C .  glacialis 
which prevails during the oligotrophic Arctic sum- 
mer and autumn. 

Potential production 

Estimates of Calanus glacialis production have 
been conducted in a dynamic model by combining 
data from population a n d  bioenergetic studies 
during the productive period in the Arctic (Slag- 
stad & Tande 1990). Based o n  an estimate in 
primary production of 6 5 g  C m - ? ,  the model 
indicates a Calanus production of 8.5 g C m-' 
during a simulation period of 150 days at 78"N 
east of Svalbard. T h e  physical-environmental 
data from the region of 78"N in 1984, where the 
ice started to disappear in May that year, was 
used in the standard run. D u e  t o  a two-year 
generation cycle, there is a bimodal seasonal pro- 
duction with a maximum during August when the 
cohort produced during the spring has developed 
to CI-CIV (Fig. 7). A tendency for a high degree 
of mismatch between the spring bloom and the 
subsequent buildup of copepod biomass in 



Calanus in North Norwegian fiords and in the Barents Sea 399 

14- 

12 

h 

c'! 1 0 -  
E 
0 

z 
3 a -  

3 
n 
B a 

Phytoplankton 
1 

- 

6- 

4 -  

z 
+ 0 Calanus glacialis 
0 
3 
D 0.12 

n 
2 
0.06 

0.00 

TIME 

Fig. 7. Timing between copepod production in Calanusglacialis 
CIV-CV and CI-CIII during the productive period in the Arctic. 

Balsfjorden is inherent in the data presented 
above. In the Arctic environment a two-year life 
cycle of C .  glacialis should enhance an improved 
ability to exploit the spring bloom and reduce the 
general tendency for mismatch and the inter- 
specific competition during the short productive 
season. 

If the rate of energy accumulation of Calanus 
glacialis in the Arctic food web is considered 
in terms of lipid classes, well-defined patterns 
emerge. The proportion of wax esters increases 
from CI to CV of C .  glacialis, and the highest 
proportions are apparent in CIV and CV (Hen- 
derson & Tande 1988). When this is considered 
in relation to the primary production in the Arctic, 
a substantial part of the wax ester deposition at 
the second trophic level tends to co-occur during 
the spring bloom (Fig. 7). In the Atlantic part of 
the Barents Sea and coastal waters of northern 
Norway C. finmarchicus (the spring and early 
summer form) and Pseudocalanus sp. (the late 
summer form) are the two quantitatively impor- 
tant copepods which rely on wax esters as their 
depot lipid. (Hopkins et al. 1984; Henderson & 
Tande unpubl. data; Norrbin et al. 1990). A two- 
year life cycle of C. glacialis gives rise to an 
analogous seasonal bimodal pattern of wax ester 
deposition in the Arctic as found in the boreal 
copepod community. 

For herbivorous copepods, the extreme con- 
ditions in the Arctic should be viewed in relation 
to the large variability in the timing and duration 
of the periods in which food is available. This 
could be related directly to the interannual vari- 
ation in the extension and retreat of ice during the 
productive season. Climatic changes with possible 
consequence for the production of C. glacialis can 
therefore be demonstrated by simulating different 
durations of the primary production period (Fig. 
8). Based on the standard model simulation, five 
different situations were defined by changing the 
ice conditions. This was done by letting the ice 
cover disappear during one weak starting in the 
middle of each month from April t o  August, and 
simulate to the end of September. The potential 
production decreased from a maximum of 12.5 to 
3 g C m-* when the onset of primary production 
changed from the middle of April to the middle 
of August. The ice conditions which could change 
the productive period from 5.5 to 1 . 5  months thus 
have the potential to reduce the production of C .  
glacialis by a factor of 4. Although estimated 
production is higher than given in the standard 

2t 

Calanus glacialis 

APR MAY JUN JUL AUG 
TIME 

Fig. 8. Effect of timing of ice melt. controlling onset of algal 
bloom in water column on production of Calanus glacialis. 



400 K .  S. Tande 

run for the model simulation in Slagstad & Tande 
(1990). the proportionate reduction in production 
should be considered relevant for this region. This 
means that during cold years, the climate would 
reduce the energy input to the lower trophic levels 
in the Arctic. This is not a consequence of low 
temperature by itself. but rather a result of the 
extent of the southern distribution of the ice dur- 
ing the productive season in the Barents Sea. 

Calanus finmarchicus 
In neritic waters from the North Sea. and in 
coastal waters o f  Norway t o  the Lofoten area. 
Culanus ,finniurchiciis is considered t o  produce 
two generations per year (Samme 1934: 0 s t v e d t  
1955: Wiborg 1955: Marshall & Orr 1972: Mat- 
thews et al. 1978). An annual life cycle is found 
in oceanic waters in the North Atlantic Current 
from OWSI (59"N; 19'W). northwards to the 
coastal waters of northern Norway and t o  the 
Polar Front in the Barents Sea (Parsons & Lalli 
1988; Tande 1982: Tande e t  al. 1985). T h e  spawn- 
ing behaviour of c'. ,finmarchicus has recently 
been described in detail in fjord areas of northern 
Norway by Die1 & Tande (1991). They have sug- 
gested that the onset of the phytoplankton spring 
bloom in the first days of April enhances the final 
maturation of ovaries and triggers the onset of 
the main spawning period. T h e  overlap of the 
estimated minimum +week spawning period of 
the individuals leads t o  a main reproductive phase 
of the population of approximately 3 weeks dur- 
ation. During this period mean clutch size and 
spawning frequency are maximal. 

Conclusive patterns of regional and seasonal 
variations in abundance and biomass are ham- 
pered because of the relatively restricted numbers 
of appropriate time series of field data from the 
Barents Sea. Maximum abundances of C. fin- 
murchicus are found during the annual recruit- 
ment period from mid-May to the end of June 
(Tande & Slagstad 1991). T h e  peak in the biomass 
5hiftr slightly. occurring two or three weeks later 
in the Barents Sea compared to Balsfjorden. when 
the population has moulted to CIV and CV 
(Tande 19x1: Tande & Slagstad 1991). A n  abun- 
dance o f  CIll and CIV. when they appeared as 
the highest proportions of the population. varied 
from 2-130 x 10'individuals m-: along a transect 
from 73 to 76"N in central parts of the Barents 
Sea at the end of June 1981 (Hassel 1986). T h e  

abundance of CI t o  CIV C. Jinmurchiclls moni- 
tored from the e n d  of May to mid-June 1987 from 
73 t o  75"N to the east of Bjarnoya, at an earlier 
stage in the annual recruitment period than 
above, varied by a factor of 10 (from 3-30 X 10') 
within the various developmental stages (Unstad 
& Tande 1991 this volume). 

Population studies of Calanus finmarchicus in 
March, April. and May 1989 from the Atlantic 
Current in the western part of the Barents Sea 
(Fig. 9) show that males outnumbered females in 
March, i.e. the period of insemination occurs 
later than in Balsfjorden (Tande & Hopkins 1981; 
Tande 1982). T h e  temperature was increased 
from 4 to 6°C at Station 6, and from 3.5 to 5.5"C 
at Station 12 from March t o  May. Regional vari- 
ations in the sex ratio a t  the different stations 
within the study region appear t o  be consistent, 
and there is a less skewed sex ratio in favour of 
males at Stations 6, 7 ,  11, and 13 in March and 
April. O n  10 May the recruitment generation of 
C. finmarchicus was found as CI a n d  CII at three 
of these four stations. This indicates that t h e  onset 
of spawning and the subsequent build-up of the 

10" 20" 30" 40" 50' 60" 70" 

80" 

10" 20" 30" 40" 50' 60" 70" 

/ \ 
i 
/ 

I /  I \ \I '\ \ 
40-- - 80" 

MAR I 

70" 

200 30' 40" 

F i g .  Y. Rcgional variation in the abundanzc ( r n - ' )  of C'cdnnus 
/inrnurchicu.\ m a l e s  and females during March a n d  April. and 
the s u h w q u e n t  build-up of CI and CII in May l Y 8 Y  in oceanic 
\ \ a t e n  of thc Barents S e a  



Calanus in Nc 

recruitment generation could differ by two weeks 
in open oceanic waters in the Barents Sea. This 
emphasises the importance of monitoring the bio- 
logical system in relation to the hydrographic 
conditions in order to obtain a more precise dif- 
ferentiation of the productive regime in the Atlan- 
tic part of the Barents Sea. 

A method of estimating the production of Cal- 
anus finmarchicus in boreal waters has been 
described by Tande & Slagstad (1991). Model 
simulations estimate the annual primary pro- 
duction to 70 g C m-z for open oceanic waters in 
the Atlantic region of the sea; this is in general 
agreement with figures provided by Rey et al. 
(1987). The estimation of Calanus production is 
based on physical data from 1983 (Fig. lo), start- 
ing with a spawning stock of 2000 adult females 
m-2. Population parameters scale the abundance 
of CI-CV according t o  the maximum recorded in 
the Atlantic region of the sea in 1983 (Skjoldal et 
al. 1987) and give a potential production of 8.5 g 
C m-* (Tande & Slagstad 1991). Copepodite 
Stages IV and V are responsible for the largest 
proportion of this production and occur during 
the culmination period from mid-June to mid-July 
in the standard run. In terms of lipid deposition 
in C. finmarchicus, wax esters are laid down in 
increasing proportions during the copepodite 

Phytoplankton 
I 

" m O'Ot APR ' MAY ' JUN ' JUL I 
v 

0 ,  Calanus finmarchicus 
L 

i, 2 0.2 
n 

0.1 

0.0 

TIME 

Fig. 10. Timing bctwccn thc copcpod production in Colanus 
finmarchicus (CI-CV and CIV-CV, rcspcctivcly) and thc cul- 
mination of the spring bloom in Atlantic waters. 

7rth Norwegian fjords and in the Barents Sea 401 

growth period (Henderson & Tande, unpubl. 
results). This is analogous to the situation 
described for the Arctic domain, in which the 
time period of wax ester accumulation takes place 
fairly early in the productive period and is coupled 
to the intensive growth and production period in 
C. finmarchicus. 

Regional variations in estimates of C. fin- 
marchicus production in temperate and boreal 
waters have been reviewed in Tande & Slagstad 
(1991). Recently, it has been suggested that cli- 
matic events play a major role in the interannual 
variability of copepod populations in the Bering 
Sea (Vidal & Smith 1986). A higher biomass of 
smaller copepod forms (Pseudocalanus spp. and 
Oithona similis) was observed in warm years than 
in cold years on the middle shelf in the south- 
eastern Bering Sea (Vidal & Smith 1986). This 
variation is related to size-dependent differences 
in metabolic rates, and copepods with small body 
sizes are proportionally more affected by tem- 
perature than by food supply (Vidal 1980a. b). 
This is exemplified for C. finmarchicus i n  the 
Barents Sea, where the standard model predicts 
a production of 12, 8, and 4 g  C m-z at tem- 
peratures of 7 ,  5, and 3°C. respectively (Fig. 11). 
Mortality according to the model is 0.11% d-I 
for the period from NI to CI. For CII-CIII, CIV, 
and CV, the mortality is set at 0.077, 0.055, and 
0.004, respectively (Tande & Slagstad 1991). This 
means that lower temperature would increase the 
stage durations and thus the total mortality of the 
recruiting generation. 

Support for the increase in production at high 
environmental temperatures is not found as an 
increase in biomass of C. finmarchicus during 
the summer in warm years in the Barents Sea. 

- - Calanus finmarchicus 
1 

TIME 

Fig. 11. Sensitivity analysis of the cffcct of temperature on thc 
potential productivity in Calanus finmarchicus. 



402 K .  S. Tande 

Abundances at 74, 75, and 76"N along a transect 
in the Polar Front region in the beginning of June 
1982 and 1983 differed in favour of the former 
year by a factor of 100 (Skjoldal et al. 1987). 
Although 1983 was generally a warmer year than 
1982, there were temperatures of about 3.5 and 
2.5"C, respectively, in the beginning of June in 
the uppermost 100 m at 75"N. These interannual 
differences should be interpreted with caution 
since the area of sampling is located in the Polar 
Front region where the biomass consisted both of 
C. glacialis and C. finmarchicus (Skjoldal et al. 
1987). For copepods with one generation per 
year, the overwintering stock of mature females 
is considered important for the subsequent pro- 
duction period (Tande & Slagstad 1991), which 
also links predation to the copepod production 
the following year. Although the differences in 
biomass found in the summer period from 1979 
to 1984 could be explained by various factors. 
large interannual variations in copepod pro- 
duction are highly probably in the Barents Sea. 

Recently, the mortality and developmental 
rates of nauplii and copepodite stages of C. fin- 
marchicus from neritic waters in northern Norway 
have been obtained both at constant and con- 
tinuously changing temperatures (Pedersen & 
Tande 1991). The temperature regimes in the 
experiments simulated three different rates of 
increase from 2°C: 0.2, 0.1, and 0°C d-I, which 
are within the range of variations in high latitude 
environments. The resulting mortality rates 
showed that increases in temperature yielded low 
mortalities for transition from nauplii and to cope- 
podite Stage I .  Thus an increase in temperature 
would reduce natural mortality in C. finmarchicus 
during the recruitment period. Populations which 
experienced 2°C continuously showed in general 
higher mortality rates in addition to arrested dev- 
elopment and mass mortality after 20 days of 
incubation. The temperature-dependent mor- 
tality rate is. at the moment, difficult to quantify 
in ecological terms. The situation is complicated 
by a possible acclimation effect of the over- 
wintering temperature experienced by the adult 
females (Pedersen & Tande 1991). The tem- 
peratures experienced by overwintering females 
appear t o  modify the relationship between tem- 
perature and developmental rates of the 
offspring. This means that there is a certain degree 
of physiological plasticity to temperature in C. 
finmarchicus which could be of ecological rel- 
evance to the species in the Barents Sea. 

Vertical organisation and temporal 
shifts in the lower food chain. 
The temporal succession and match-mismatch 
between primary production and the growth 
cycles of Calanus glacialis and C. finmarchicus, 
described above reinforce the question of food 
limitation of these copepods during the pro- 
ductive period in the Barents Sea. 

The highly layered structure of the pelagic eco- 
system has been suggested as the primary spatial 
variance in the ocean (Longhurst 1981). In coastal 
waters of northern Norway and in the Barents 
Sea the seasonal (ontogenetic) vertical migration 
patterns in C. finmarchicus tend to coincide with 
the annual generation cycle (Unstad & Tande 
1991). In these areas CI-CIII tended t o  aggregate 
in the uppermost waters in May and June (Tande 
1988b; Unstad & Tande 1991). Ontogenetic ver- 
tical migrations were apparent in almost all 
locations studied, and the maximum abundance 
was, to a variable degree, associated with the 
maximum of algal biomass. The magnitude of 
diurnal vertical migration varied, and consider- 
able differences in vertical translocations in the 
abundance were found in Malangen as compared 
to Grotsund and Balsfjorden (Tande 1988b). In 
the Barents Sea, the vertical separation of cope- 
podite stages tended to increase at locations with 
the absence of a well-defined phytoplankton 
maximum, both at high and low phytoplankton 
standing crops. In waters where C .  finmarchicus 
and C. glacialis coexisted at high population den- 
sities, a tendency toward a clear bimodal dis- 
tribution pattern was found which could facilitate 
a decrease in competition for similar food 
resources. 

The phytoplankton biomass is often both ver- 
tically and regionally dominated by the prym- 
nesiophyte Phaeocystis pouchetii during the most 
intensive growth and production period of C. 
finmarchicus. Given a suitable prey size C. fin- 
marchicus grazed on both diatoms and colonies 
of the gelatinous algae at equal rates in laboratory 
studies (Hansen et al. 1991). A linear relationship 
between gut content and food concentrations 
below 10 pg plant pigment I - '  was found. These 
data emphasise that ingestion in C. finmarchicus 
might be linearly proportional to ambient food 
concentration in May and June (cf. Fig. 10). 
Although P. pouchetii is likely to sustain growth 
in all life stages of C. finmarchicus during the 
culmination period and the early part of the oli- 



Calanus in North Norwegian fjords and in the Barents Sea 403 

gotrophic summer period, substantial regional 
variations in algal biomass and C. finmarchicus 
abundance was found both in the fjords in north- 
ern Norway during 1986 (Tande 1988b) and in 
the Barents Sea in 1987 (Unstad & Tande 1991). 
Longterm interannual variations in abundance 
and biomass of Calanus spp. are found during the 
summer periods from 1959 to 1977 (Degtereva 
1979) and from 1979 t o  1984 (Skjoldal & Rey 
1989) in the southwestern and central parts of the 
Barents Sea, respectively. The annual production 
of Calanus has been found t o  be positively cor- 
related t o  the size of the overwintering stock of 
adult females both in model analysis (Tande & 
Slagstad 1991) and also in field studies from the 
North Sea (Colebrook 1979). Thus food-limited 
growth and production by C. finmarchicus in 
Atlantic Water of the Barents Sea is more likely 
to take place in regions with high copepod abun- 
dances than through mismatch in the cycles 
between the diatoms, P .  pouchetii, and the cope- 
pod. 

The feeding conditions of the different life 
stages of C. glacialis during the oligotrophic 
period in the Arctic are defined to a large extent 
by the algal species sedimenting from the euphotic 
layer (c.f. Eilertsen et al. 1989). Colonial forms 
such as P. pouchetii and the mixotroph Dinobryon 
sp. are common in the layer, although low num- 
bers of diatoms could generally be indicative of 
selective grazing. In situ feediqg rates above those 
expected from ambient diatom concentrations are 
found at locations where colonial forms prevail, 
increasing the trophodynamic importance of the 
colonial forms (Hansen et al. 1990). Alternative 
food organisms have not been considered in these 
studies, but diatoms, flagellates, and ciliates were 
found in the diets of Calanus spp. in polynyas, at 
the ice edge and in open waters in June and July 
in the Fram Strait (Barthel 1988). Recent data 
show that Protistan plankton consume a greater 
fraction of plant production than Metazoa, and 
Protista would alter the overall quantity and ver- 
tical pattern of carbon flow between plant pro- 
ducers and Calanus spp. in the Arctic. 

A deep-water chlorophyll maximum layer 
(SCM) is usually formed around the nutricline 
during the Arctic summer period by a gradual 
descent of the spring surface blooms (Tande & 
Bimstedt 1985; Eilertsen et al. 1989; Longhurst 
& Harrison 1989). The SCM is a temporal 
phenomenon which tracks the deepening mixed 
layer, lasts during the oligotrophic period, and is 

eroded at the end of the productive period in 
autumn. The situation has been clearly demon- 
strated in Arctic waters east of Svalbard at the 
end of July (Eilertsen et al. 1989). Here the 
vertical profiles in algal biomass (in terms of 
carbon) tracks the phytoplankton carbon assimi- 
lation, although the data do not facilitate a sep- 
aration of the production maximum from the algal 
biomass maximum. However, the biomass of the 
principal herbivores (i.e. Calanus spp.) are found 
within the algal production layer, although they 
are shifted slightly towards deeper waters. Onto- 
genetic differences in vertical distributions within 
both C .  glacialis and C. hyperboreus offset the 
vertical profiles of grazing and algal production 
to an even larger extent. Vertical profiles of algal 
production and grazing vary extensively in the 
region of the Polar Front during the post-bloom 
period (Hansen et al. 1990). This emphasises the 
anticipated spatial heterogeneity which is often 
found in the vertical coupling of algal production 
and zooplankton grazing in frontal systems due 
to variability in the physical environment. On the 
other hand, the striking offset of the vertical 
distribution of the primary producers relative to 
macrozooplankton during the oligotrophic Arctic 
summer period favours the existence of the SCM. 
Therefore, the question of food limitation in C .  
glacialis in the Arctic environment should be 
viewed in an evolutionary context where the feed- 
ing behaviour. vertical behavior and life cycle 
strategy are adjusted to facilitate an optimal har- 
vesting strategy of the Arctic phytoplankton com- 
munity both on a temporal and a regional scale. 

Calanus productivity: an interplay 
between endemic and advective 
processes 
The large-scale periodic changes in temperature 
are shown by temperature anomalies (Fig. 12) 
during a 25 years period in the Kola section 
33"30'E) in the Barents Sea (Midttun & Loeng 
1987). Warm and cold periods alternate in periods 
of 3-5 years and are closely related to the ice 
conditions (Blindheim & Loeng 1981). Midttun & 
Loeng (1987) have suggested that these variations 
are related to variations in the inflowing Atlantic 
Water. Thus, temperature changes in the eastern 
part of the Barents Sea usually occur one year 
later than in the western part (Loeng et al. 1983). 



404 K .  S. Tande 

L) 0.5 0.5 

-4 
" - 0  0 

-0.5 -0 5 
-1.0 .l .o 
- 1  5 -1.5 

Fig I 2  Sca temperature anomalie, durlng the period from 1960 
to 1985 along the Kold bectlon in the Bdrcnts Sea Redrawn 
from Midttun & Loeng (1087) 

To what extent the temperature changes shown 
in Fig. 12 reflect variations in inflowing activity 
or properties of the Atlantic Water is debatable. 
However, it is obvious that the Atlantic Water is 
modified by local processes in the Barents Sea, 
where cooling and ice formation result in water of 
higher density. Cooling and ice formation change 
inflowing Atlantic Water into dense bottom 
water, which promotes outflow through the chan- 
nels (particularly through Bjarnoyrenna) leading 
out from the Barents Sea. A large inflow would 
then be followed by a period of cooling and modi- 
fication of the Atlantic Water. This could be one 
reason for the apparently cyclic variation in the 
ocean climate particularly i n  the Atlantic region 
of the Barents Sea. 

The functioning of Calanus glacialis and C. 
Jinniarchicus within these physical conditions 
could be described in different scenarios. Ex- 
tremely cold years are associated with a southern 
distribution of the ice during the spring. This 
situation would tend to decrease the potential 
secondary production i n  Arctic and Atlantic 
waters. but through different mechanisms. The 
Arctic domain should be considered as an unpre- 
dictive environment for C. glacialis since the 
northward-flowing water currents in the eastern 
area would counteract the anticipated increase 
i n  production following the ice withdrawal. This 
would tend to delay the onset of the spring bloom 
with a consequently negative effect on the poten- 
tial production of the proportion of the population 
present i n  these regions. The opposite situation 
could be found for C. glacialis in the western 
region where the Arctic Water flows in the oppo- 
site direction. Cold periods would not tend to 
alter the overall pattern of primary production in 
the Atlantic Water, but would tend to lower the 
potential productivity in "@marchicus" water 

more directly through temperature. The cooling 
would enhance the negative effect on dev- 
elopment and mortality rates because the antici- 
pated temperature increase during the spring and 
early summer would be low or absent i n  certain 
regions. Advection would increase the transport 
of biomass to the Barents Sea. increase the extent 
of the productive "finmarchicus" area, and pro- 
mote the endemic productivity in both the Atlan- 
tic and the Arctic region of the Barents Sea. 

The food chain from Calanus to planktivorous 
fish and gelatinous zooplankters is therefore 
dependent upon productivity changes endemic to 
the sea and upon advection of biomass from Polar 
Water, the Norwegian Sea, and the Norwegian 
Coastal Current. The Barents Sea is considered 
as a nursery area for the young year classes of 
Atlanto-Scandian herring (Dragesund et al. 
1980). Capelin (Mallofus uillosus) and polar cod 
(Boreogadus saida) are endemic planktivorous 
fishes inhabiting both Atlantic and Arctic waters 
(Hamre 1985; Monstad & Gjosaether 1987). 
Although large fluctuations in the stocks have 
been detected during the 1970 and 1980s. Skjoldal 
& Rey (1989) believe that these two species act 
as competitors on the zooplankton biomass and 
production. The interannual variability in plank- 
ton biomass found in the different regions of the 
sea (i.e. Degtereva 1979; Skjoldal & Rey 1989) 
is probably related to large scale processes. The 
way in which these trophodynamic couplings are 
expressed in quantitative dynamic terms is at 
present largely unknown. In order to substantiate 
these important links, future research in the Bar- 
ents Sea should be designed to cover three topics: 
firstly, a description of the dynamics in the large- 
scale advective processes, especially from the 
North Atlantic and the Norwegian Coastal cur- 
rents with monitoring of the biomass involved 
and the biological consequences for the different 
regions in the Barents Sea; secondly, a more 
elaborate understanding of the harvesting strat- 
egy of fish on the principal planktivores on cope- 
pods and krill in the different regions of the 
Barents Sea proper; and thirdly, experimental 
studies in conjunction with field investigations in 
order to further substantiate the effect of climate 
on the biological rate processes among key species 
in the Atlantic region of the Barents Sea. 

Acknowledgemeno. - This work I S  part of the Pro Mare pro- 
grammc and was financially supported in part by the Nonvcgian 
Fisheries Research Council (NFFR). The author wishcs to thank 
two anonymous reviewers for valuable comments on the manu- 



Calanus in North Norwegian fiords and in the Barents Sea 405 

script and D. Slagstad for performing thc simulation test and 
for the stimulating discussions. 

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