No Job Name


Late Quaternary foraminiferal record in Murchisonfjorden,
Nordaustlandet, Svalbardpor_173 283..297
Frauke Kubischta,1 Karen Luise Knudsen,2 Anu Kaakinen1 & Veli-Pekka Salonen1

1 Department of Geosciences and Geography, Division of Geology, University of Helsinki, Gustaf Hällströmin katu 2a, PO Box 64, FI-00014 Helsinki,

Finland

2 Department of Earth Sciences, Aarhus University, Høegh-Guldbergs Gade 2, DK-8000 Århus C, Denmark

Abstract

Benthic foraminiferal assemblages from Nordaustlandet, Svalbard, are
described for the first time with the objective of reconstructing the palaeoen-
vironmental conditions in the area during the late Quaternary. Investigations
were carried out on marine deposits exposed along the southern shores of
Murchisonfjorden. Five foraminiferal assemblages (A1–A5), representing dif-
ferent palaeoenvironmental conditions, were identified from the marine
intervals, i.e., the Cassidulina reniforme–Elphidium albiumbilicatum assemblage
(A1) from the Early Weichselian, the Islandiella helenae–Cibicides lobatulus
assemblage (A2) from the Early Weichselian, the Cibicides lobatulus–Cassidulina
reniforme assemblage (A3) from marine isotope stage 3, the Elphidium albium-
bilicatum assemblage (A4) from the early Holocene and the Astrononion
gallowayi assemblage (A5) from the mid-Holocene. Assemblages A1–A5 are
compared with modern and fossil Quaternary assemblages from Arctic regions.
Particularly notable is the fact that a well-defined Middle Weichselian assem-
blage in Svalbard is described for the first time, i.e., the Cibicides lobatulus–
Cassidulina reniforme assemblage. All the assemblages from Nordaustlandet
represent glacier-distal, inner-shelf environments with an open connection to
the ocean. The results reveal the occurrence of three marine intervals (ice-free
periods) in the north-western part of Nordaustlandet during the Weichselian,
as well as ice-free conditions during most of the Holocene. A comparison of the
assemblages from Nordaustlandet with previously published foraminiferal
zones from onshore sections elsewhere in Svalbard show some degree of
similarity, but also show considerable variation in species compositions, pre-
sumably caused by local environmental differences.

Keywords
Quaternary stratigraphy; benthic

foraminifera; palaeoenvironments; Arctic;

Svalbard.

Correspondence
Frauke Kubischta, Department Geosciences

and Geography, Division of Geology,

University of Helsinki, Gustaf Hällströmin katu

2a, PO Box 64, FI-00014 Helsinki, Finland.

E-mail: frauke.kubischta@helsinki.fi

doi:10.1111/j.1751-8369.2010.00173.x

Nordaustlandet is the north-easternmost island of the
Svalbard archipelago (76–81°N, 10–30°E; Fig. 1), sepa-
rated from the main island, Spitsbergen, by
Hinlopenstretet. Much of Nordaustlandet is covered by
two large ice caps, Vestfonna and Austfonna, and only
small areas along the northern, north-western and south-
ern coasts are free of ice (Fig. 1). Rapid isostatic uplift
after the last deglaciation has led to the exposure of
marine deposits that are now accessible in a number of
vertical coastal sections, a few metres high, containing
rich biostratigraphical and sedimentological information
(Blake 1961, 1981).

To complement previous studies on the stratigraphy of
Quaternary sediments from around Svalbard by Lønne &

Mangerud (1991), Mangerud & Svendsen (1992), Ander-
sen et al. (1996) and Houmark-Nielsen & Funder (1999),
Kaakinen et al. (2009) have performed sedimentological
studies at a series of exposures in the south-eastern part
of Murchisonfjorden, Nordaustlandet. They found that
marine sands and gravels are interlayered with tills deriv-
ing from multiple glacier advances throughout the
Weichselian. These marine sands and gravels were also
found to contain pelecypod remains and foraminifera,
but the faunal material in the sections was not investi-
gated in any detail.

Overall, Quaternary research on Nordaustlandet
has previously focused on glacial geology, geomorpho-
logy and palaeolimnological studies, rather than on

Polar Research 29 2010 283–297 © 2010 the authors, journal compilation © 2010 Blackwell Publishing Ltd 283

mailto:kubischta@helsinki.fi


Fig. 1 (a) Location of the study area in
Murchisonfjorden in the north-western part of

Nordaustlandet, Svalbard, with an inserted

close-up of the Murchisonfjorden area, and

(b) the sections in Isvika. Abbreviations:

B., Brøggerhalvøya; Bl., Blåfjorddalen; G.,

Guldalen; K., Kongsfjordhallet; K.W., Kapp

Wijk; L., Linnéelva; P., Poolepynten; Sa.,

Sarsbukta; Sk., Skilvika; T., Talavera; V.,

Visdalen; Wi., Wijdefjorden.

Late Quaternary foraminiferal record in Murchisonfjorden, Nordaustlandet, Svalbard F. Kubischta et al.

Polar Research 29 2010 283–297 © 2010 the authors, journal compilation © 2010 Blackwell Publishing Ltd284



biostratigraphy and sedimentology of the marine depos-
its. Donner & West (1957, 1995) examined the
Weichselian deglaciation and emergence history at
Brageneset (Fig. 1), and reported observations on the
glacial geology of Nordaustlandet. The ice-movement
history of Nordaustlandet, including the radiocarbon age
determination of raised beaches, land uplift, morphologi-
cal investigations and climatic implications of the
occurrence of Mytilus edulis, were studied by Blake (1961,
1962, 2006). In his PhD thesis, Blake (1962) even
described reworked foraminifera within tills in the
Murchisonfjorden area.

Hyvärinen (1969, 1970) established a pollen stratigra-
phy for the last 10 000 years based on lake sediment
records from Nordaustlandet and Spitsbergen. These
studied cores also revealed marine strata with abundant
benthic foraminifera, but Hyvärinen (1969) only men-
tioned three taxa, determined to genus level, from the
marine interval. This points to a clear lack of knowledge
of the marine biostratigraphy of the area.

Foraminiferal palaeoecological and stratigraphical
studies have, however, previously been performed for
several core records from fjords and the adjacent shelf
areas in Svalbard (e.g., Svendsen et al. 1996; Wollen-
burg et al. 2001; Koç et al. 2002; Hald et al. 2004;
Ślubowska et al. 2005; Korsun et al. 2006; Rasmussen
et al. 2007; Ślubowska-Woldengen et al. 2007; Hald &
Korsun 2008; Majewski et al. 2009), as well as for raised
marine deposits from coastal sections around the archi-
pelago (e.g., Feyling-Hanssen 1965; Nagy 1984; Miller
et al. 1989; Landvik et al. 1992; Lycke et al. 1992;
Mangerud et al. 1992; Svendsen & Mangerud 1992;

Ingólfsson et al. 1995; Bergsten et al. 1998; Mangerud
et al. 1998).

The aim of this study is to examine the micropalaeon-
tological record from some of the raised marine deposits
in Murchisonfjorden, Nordaustlandet, and to use the
benthic foraminifera to infer, on a relative and qualitative
basis, the palaeoenvironmental conditions such as water
temperature, salinity, water depth and current energy for
the Late Quaternary in the area. This is achieved by a
comparison with modern assemblage distributions of
foraminifera, particularly in the Svalbard area, but also in
adjacent Arctic regions such as northern Norway, north-
ern Russia and Greenland. In addition, an attempt is
made to correlate the different marine units in the coastal
sections in Murchisonfjorden with similar deposits
described from other onshore sections around the
Svalbard archipelago.

Late Quaternary sections in Murchisonfjorden

The research material presented here was collected from
a coastal area west of Vestfonna during a 3-week-long
field campaign in July–August 2007. The seven sections,
which were recently reported on by Kaakinen et al.
(2009) are situated along the shores of Isvika on the
southern side of Murchisonfjorden in Nordaustlandet,
Svalbard (Fig. 1). Only five of these sections were used
for optically stimulated luminescence (OSL) dating and
for the present study (Fig. 2). Kaakinen et al. (2009)
identified a total of 12 lithofacies units, and recognized
evidence from three depositional sequences. Each
sequence includes till unit(s) overlain by sorted marine

Fig. 2 Lithostratigraphical correlations of the sections in Isvika, Murchisonfjorden, with indication of sediment facies, unit numbers, foraminiferal sample
locations and mean ages. Modified from Kaakinen et al. (2009).

Late Quaternary foraminiferal record in Murchisonfjorden, Nordaustlandet, SvalbardF. Kubischta et al.

Polar Research 29 2010 283–297 © 2010 the authors, journal compilation © 2010 Blackwell Publishing Ltd 285



sands and gravels. The sedimentological analyses indi-
cated that the tills were deposited as a result of
lodgement, melt-out and deformation processes, whereas
the raised marine strata were interpreted to represent
upper shoreface, foreshore, and littoral gravels and beach
deposits.

The ages of the deposits, which were constrained by
OSL dating of well-bleached quartz grains and accelerator
mass spectrometry (AMS) 14C age determinations of
shells, range from over 80 Ky to around 6 Ky (Kaakinen
et al. 2009). Two samples gave ages within the time frame
of the Phantomodden Interstadial, marine isotope stage
(MIS) 5c-a (Mangerud et al. 1998), and one was dated to
MIS 3 and correlated with the Kapp Ekholm Interstadial.
Four age determinations cover the Holocene epoch, with
the oldest results being close to the time of the deglacia-
tion of the island, and two results representing the
mid-Holocene.

The grain sizes of the marine strata ranges from
clayey silt to gravel, and they contain a rich macro- and
microfauna such as Mya truncata, Astarte sp., Hiatella
arctica, Astarte borealis and Chlamys islandica, foraminifera
and some ostracoda, although in varying states of
preservation.

The younger shells are better preserved, less mechani-
cally abraded and have been exposed less to calcareous
dissolution than those in the older units. The relatively
poor preservation of both macro- and microfossil shells in
the older sediments is considered to be the result of over-
riding during subsequent glaciations, plus frost action and
post-depositional solifluction, but the foraminiferal tests
may also have been damaged further during the labora-
tory treatment (see below).

Material and methods

The nine samples that were available for this foramin-
iferal study were originally used to determine water
contents of the sediment units, from which OSL dates
were obtained (sediment units 1, 2, 6, 8, 11 and 12; no
OSL dates were carried out from units 5, 7, 9 and 10)
(Kaakinen et al. 2009). As a result of the required labo-
ratory treatment for water content determination
(heating to 105°C for several hours), some specimens,
particularly small or thin-shelled tests and agglutinated
tests, may have been damaged. Yet, we consider the
material to be sufficient for this first overview of fora-
miniferal assemblages in the Quaternary deposits of
Nordaustlandet.

After drying (dry weights vary from 40.2 to 49.6 g), the
samples for foraminiferal analysis were wet-sieved
through a stack of sieves with mesh sizes of 1.000, 0.250,
0.125 and 0.063 mm. The fractions were dried on the

sieves and then stored in glass vials for future analysis.
For foraminiferal analysis, the 0.125-mm fraction was
concentrated by soap flotation to avoid the excessive use
of chemicals, and was again dried in an oven at 50°C. In
two samples (samples 13 and 41), the foraminiferal shells
were still mixed with sand grains after flotation with
soap. Therefore, the usual heavy liquid method (C2Cl4)
was subsequently applied for the preparation of these,
following the method described by Feyling-Hanssen et al.
(1971) and Knudsen (1998).

Of the nine samples that were available for foramin-
iferal analysis (Fig. 2), one did not contain any
foraminifera (sample 20), and one contained only two
specimens of Cibicides lobatulus (sample 19; Table 1). These
two samples are not further discussed. In samples with
low abundances of foraminifera (samples 14, 7, 8, 27, 42
and 41), all the specimens were determined and picked,
but only approximately one-eighth of sample 13 was
counted. A total of 21 calcareous benthic taxa were iden-
tified. One sample (14) contained a single planktonic
specimen. Agglutinated species are generally not pre-
served in this kind of material, and only a few specimens
were found.

The counts and the original references for all the
species and species groups are listed in Table 1. The
number of specimens per 100 g of dry sediment is gener-
ally low, ranging from ca. 75 to 14 200 in the fossiliferous
samples. A faunal diversity index, defined by Walton
(1964) as the number of ranked species that accounts for
95% of a counted assemblage, was applied to the assem-
blages. This faunal diversity index and the number of
benthic calcareous species have values of 6–10 and 7–15,
respectively.

Elphidium albiumbilicatum and Elphidium hallandense are
grouped as Elphidium albiumbilicatum/hallandense in one
of the samples (sample 13; Fig. 3; Table 1), because the
occurrences of transition forms between the two species
made a separation difficult. Both species indicate shallow
and/or brackish conditions, but as Elphidium hallandense is
a High-Arctic species, whereas Elphidium albiumbilicatum
often occurs in sub-Arctic waters, a possible climatic indi-
cation may be lost by this grouping (see the discussion in
Knudsen 1978). However, the climatic indication of
Elphidium albiumbilicatum is still relatively uncertain, as
discussed by Hansen & Knudsen (1995).

Because of the poor preservation state, some species
of the genus Elphidium have also been grouped (as
Elphidium spp.). This group is suggested primarily to
include Elphidium excavatum f. clavata, Elphidium albium-
bilicatum and Elphidium hallandense. Elphidium spp. is a
shallow-water group that is generally tolerant to changes
in salinity (e.g., Murray 1991, 2006). Species within the
family Polymorphinidae are also grouped. Agglutinated

Late Quaternary foraminiferal record in Murchisonfjorden, Nordaustlandet, Svalbard F. Kubischta et al.

Polar Research 29 2010 283–297 © 2010 the authors, journal compilation © 2010 Blackwell Publishing Ltd286



and planktonic taxa are not included in the percentage
calculations of Fig. 3.

Foraminiferal assemblages and
palaeoenvironments

Five foraminiferal assemblage zones (A1–A5) were iden-
tified on the basis of the faunal compositions in the
material from Nordaustlandet, according to the definition
by Salvador (1994). Assemblage zones A1–A3 are repre-
sented by only one sample each, whereas assemblage
zones A4 and A5 are comprised of two samples each. The
percentage distribution of foraminiferal taxa in assem-
blage zones A1–A5 is shown in Fig. 3 together with a
composite lithostratigraphical log, the facies sequences,
the sedimentary units and the mean age of each sample
(after Kaakinen et al. 2009). A description of the foramin-
iferal contents of each assemblage zone is given below,
together with a palaeoenvironmental interpretation,

which is summarized in Table 2. The lithological descrip-
tions and age determinations are based on earlier
investigations in the area (Kaakinen et al. 2009).

Assemblage zone A1: Cassidulina reniforme–
Elphidium albiumbilicatum assemblage
(sample 41)

Description. The sediment consists of well-sorted fine
to medium sand with both whole and broken pelecypod
shells, mainly of Mya truncata. The sample contains an
extremely rich foraminiferal assemblage with a faunal
diversity of 7, and is dominated by Cassidulina reniforme
and Elphidium albiumbilicatum, with Buccella frigida and
Islandiella helenae as the second most abundant species.
Elphidium excavatum (as forma clavata; see Feyling-
Hanssen 1972), Haynesina orbiculare, Cibicides lobatulus,
Nonionellina labradorica and Elphidium hallandense also
play an important role (Fig. 3).

Table 1 Foraminiferal counts and faunal characteristics of eight samples from Isvika, Murchisonfjorden, Svalbard. The original references and descrip-
tions of the taxa are reported in Ellis & Messina (1949, and supplements up to 2007). For logs and sedimentary units, see Figs. 2 and 3. Agglutinated and

planktonic foraminifera are excluded from the percentage calculations of Fig. 3.

Sample no. 19 14 13 7 8 27 42 41

Log/unit 4 3/8 3/8 2/12 2/11 5/6 7/2 7/1
Sample weight in g (dry) 45 40 41 46 44 46 50 45
Specimens counted 2 224 734 237 320 117 34 825
Specimens per 100 g of sediment 560 1780 510 720 250 75 14200

Faunal diversity (Walton 1964) 10 10 6 8 8 7

No. of species 1 13 15 12 14 11 7 14

Assemblage no. A5 A5 A4 A4 A3 A2 A1

Astrononion gallowayi Loeblich & Tappan, 1953 38 342 21 44 6 1

Buccella frigida (Cushman, 1922) 12 13 3 3 3 2 91

Cassidulina reniforme Nørvang, 1945 31 150 35 43 25 1 314

Cibicides lobatulus (Walker & Jacob, 1798) 2 36 28 54 38 37 10 5

Elphidium albiumbilicatum (Weiss, 1954) 20 47 70 108 177

Elphidium albiumbilicatum/hallandense 17

Elphidium excavatum (Terquem, 1875) 28 22 33 29 14 4 65

Elphidium hallandense Brotzen, 1943 18 29 22 3 9

Elphidium incertum Williamson, 1858 1

Elphidium magellanicum Heron-Allen & Earland, 1932 1

Elphidium spp. 7 12 6 3 5 2 7

Fissurina spp. 7 1

Haynesina orbiculare (Brady, 1881) 5 42 1 2 1 15

Islandiella helenae Feyling-Hanssen & Buzas, 1976 13 9 3 17 14 114

Lagena spp. 2

Nonionellina labradorica (Dawson, 1860) 5 12 22 16 4 9

Nonion matchigaricus Voloshinova, 1952 6

Patellina corrugata Williamson, 1858 1 5

Stainforthia loeblichi (Feyling-Hanssen, 1954) 2 3

Trifarina fluens (Todd, 1947) 1

Polymorphinidae 9 3 2 1 9

Indeterminate, calcareous taxa 1 4 6

Agglutinated species 4 1 7

Planktonic species 1

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Fig. 3 Percentage distribution of benthic foraminifera from sections in Isvika, Nordaustlandet. Actual counts are inserted for sample 42, which was poor
in specimens. A composite lithostratigraphic log is shown on the left-hand side, together with the sedimentary units and facies according to Kaakinen

et al. (2009), and the subdivisions in foraminiferal assemblage zones A1–A5 are indicated on the right-hand side.

Late Quaternary foraminiferal record in Murchisonfjorden, Nordaustlandet, Svalbard F. Kubischta et al.

Polar Research 29 2010 283–297 © 2010 the authors, journal compilation © 2010 Blackwell Publishing Ltd288



Palaeoenvironment and age. Cassidulina reniforme is
an Arctic indicator species (e.g., Hald & Korsun 1997).
The relatively high abundance of specimens of the genus
Elphidium would indicate relatively shallow water and/or
fluctuating salinity (Murray 1991, 2006), and Elphidium
albiumbilicatum may be an indicator for mild sub-Arctic
conditions, as well as for shallow conditions and reduced
salinity (e.g., Lutze 1965; see discussion in Knudsen
1978). It does, however, also occur in open ocean condi-
tions off north and north-west Iceland (Rytter et al. 2002;
Jennings et al. 2004). Islandiella helenae is, on the other
hand, a High-Arctic open-ocean species requiring stable
salinity (Korsun et al. 1995; Hald & Korsun 1997), and
Cibicides lobatulus is an attached species indicating rela-
tively strong bottom-water currents (Haynes 1973;
Murray 1991, 2006; Hald & Korsun 1997). This latter
species also prefers relatively shallow but open marine
environments (Hansen & Knudsen 1995; Rytter et al.
2002). In summary, assemblage zone A1 was most prob-
ably deposited in relatively open marine waters on the
inner shelf during a high sea-level stand.

Kaakinen et al. (2009) interpreted the present sandy
bed as a slab/layer, which had been incorporated into the
glacial diamicton of sedimentary unit 1 (Figs. 2, 3), and
the well-preserved foraminifera are considered to repre-
sent an in situ assemblage. The age of sedimentary unit 1
has been estimated to 93–65 Ky, i.e., Early Weichselian

(Kaakinen et al. 2009), and the marine sedimentary unit
is considered to represent an interval of high sea-level
stand.

Assemblage zone A2: Islandiella helenae–
Cibicides lobatulus assemblage (sample 42)

Description. The sediment consists of bimodal pebble-
rich, very coarse stratified sand with some shell fragments
(unit 2; Figs. 2, 3). The assemblage, which is poor in
foraminifera, is dominated by large specimens of Islandi-
ella helenae and Cibicides lobatulus, together with Elphidium
excavatum f. clavata. Accessory species are Elphidium spp.,
Buccella frigida and Haynesina orbiculare.

Palaeoenvironment and age. The dominance of large
robust specimens in this fauna presumably indicates that
it represents a residual fauna, in which the smaller speci-
mens have been dissolved or mechanically damaged, and
the fine particles have been washed out. Another possi-
bility is that the specimens have been redeposited into
this unit from an older deposit. Islandiella helenae and
Cibicides lobatulus both indicate open-ocean and glacier-
distal environments, and additionally, Cibicides lobatulus is
a high-energy indicator. Buccella frigida is often found
together with Cibicides lobatulus in glacier-distal environ-
ments with relatively stable salinity (Haynes 1973), and it

Table 2 Stratigraphical correlation and environmental interpretation of the five foraminiferal assemblages, A1–A5, from Isvika, Murchisonfjorden.

Assemblages Environments Stratigraphical correlation

A5

Astrononion gallowayi

Glacier-distal, inner shelf

Open ocean connection

Relatively stable environment

Slightly lowered salinity

Upwards increase in bottom-water currents

Mid-Holocene

A4

Elphidium albiumbilicatum

Glacier-distal, inner shelf

Open ocean connection

High-energy environment

Slightly lowered salinity

High-energy environment

Seasonal sea-ice cover

Early Holocene

A3

Cibicides lobatulus–Cassidulina reniforme

Glacier-distal, inner shelf

Open ocean connection

High-energy environment

Relatively stable salinity

Middle Weichselian

(MIS3)

A2

Islandiella helenae–Cibicides lobatulus

Glacier-distal, inner shelf

Open ocean connection

High-energy environment

Early Weichselian

A1

Cassidulina reniforme–Elphidium albiumbilicatum

Glacier-distal, inner shelf

Open ocean connection

Relatively stable environment

Slightly lowered salinity

High foraminiferal productivity

Early Weichselian

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is often related to sandy sediments (e.g., Hansen &
Knudsen 1995; Hald & Korsun 1997). It is difficult to
interpret a residual assemblage, but there is some indica-
tion of a glacier-distal, high-energy environment for
assemblage zone A2. The interpretation of a lag deposit
for this zone is supported by the sedimentological indica-
tion of an upper shoreface to foreshore environment of
unit 2 (Kaakinen et al. 2009). The age of this unit has
been estimated to 93–73 Ky, i.e., Early Weichselian
(Kaakinen et al. 2009).

Assemblage zone A3: Cibicides lobatulus–
Cassidulina reniforme assemblage
(sample 27)

Description. The sediment consists of well to moder-
ately sorted very coarse sand and granules, as well as thin
pebble beds with sharp bases and occasional cobble hori-
zons (unit 6; Figs. 2, 3). The assemblage has a faunal
diversity of 8 and is dominated by Cibicides lobatulus and
Cassidulina reniforme, followed by Elphidium excavatum f.
clavata and Islandiella helenae, as well as several other
accessory species. It differs from assemblage zone A1 by a
decrease in the percentage of Buccella frigida, and by an
increase in Cibicides lobatulus, as well as in most of the
accessory species (Fig. 3).

Palaeoenvironment and age. The dominance of the
two species Cibicides lobatulus and Cassidulina reniforme in
this assemblage indicates deposition in an Arctic, rela-
tively shallow environment with strong bottom-water
currents. Both Cibicides lobatulus and Islandiella helenae
indicate glacier-distal conditions, whereas the influence
of the opportunistic Elphidium excavatum f. clavata would
be an indication of less stable environmental conditions
(see Hald et al. 1994). Astrononion gallowayi often occurs
together with Cibicides lobatulus in areas with strong
bottom currents and stable salinity (Hald & Korsun
1997; Rytter et al. 2002). Assemblages dominated by
Cibicides lobatulus are recorded in high-energy environ-
ments in the fjords of Svalbard, often related to shallow
thresholds across the fjords (Hald & Korsun 1997,
Elverhøi et al. 1980), and in fjord and inner shelf
areas of eastern Greenland (Jennings & Helgadóttir
1994).

In summary, the environmental indication of assem-
blage zone A3 is rather close to that of assemblage zone
A1, although with relatively stronger bottom currents.
The faunal indication of a high energy level at the sea
floor is in agreement with the interpretation of upper
shoreface to littoral gravels with beach deposits for sedi-
mentary unit 6 (Kaakinen et al. 2009). Ages of 37.0 and

40.0 Ky were obtained, i.e., a Middle Weichselian age
(MIS 3) (Kaakinen et al. 2009).

Assemblage zone A4: Elphidium albiumbilicatum
assemblage (samples 8 and 7)

Description. Sample 8 was collected from a sandy
pebble gravel bed with shell fragments, which grades
upward into shingle gravel (unit 11). Sample 7 was
obtained from a clast-supported diamicton bed with a fine
sand matrix containing shell fragments (unit 12; Figs. 2,
3). Elphidium albiumbilicatum and Cibicides lobatulus are
the dominant species, there are high abundances of
Astrononion gallowayi, Cassidulina reniforme and Elphidium
excavatum f. clavata, and several accessory species occur.
The faunal diversity is 8 in the lower sample and 6 in the
upper sample. Compared with the underlying marine
beds, this assemblage is particularly characterized by
the pronounced increase in Astrononion gallowayi and
Elphidium albiumbilicatum, and Nonionellina labradorica is
more frequent than has been previously seen. The
occurrence of Stainforthia loeblichi is unique for assem-
blage A4.

Palaeoenvironment and age. The strong influence of
Cassidulina reniforme, Elphidium excavatum f. clavata and
Buccella frigida, together with Cibicides lobatulus and
Elphidium hallandense indicate Arctic, shallow-water con-
ditions and relatively strong bottom currents. The
disappearance of Elphidium hallandense, which prefers a
silty and sandy sea floor (Hansen & Knudsen 1995), in
sample 7 may be a result of relatively high current veloc-
ity, as also indicated by the coarsening of the sediment
towards the top of the unit (Fig. 3). This idea is supported
by the appearance of Cibicides lobatulus in sample 8. The
presence of species such as Nonionellina labradorica and
Astrononion gallowayi indicates a relatively stable salinity
in a glacier-distal environment (e.g., Korsun et al. 1995;
Hald & Korsun 1997), whereas Stainforthia loeblichi is con-
sidered to be an indicator of seasonal ice cover in the area
(Steinsund 1994).

The environmental indication of assemblage A4 sup-
ports the interpretation by Kaakinen et al. (2009) of a
foreshore zone for the sedimentary environment of
sample 8 (unit 11). Their interpretation of unit 12 as
representing a debris flow cannot be confirmed from the
assemblage. If it represents a re-deposited fauna, as sug-
gested by the age determination, it could originate from a
marine environment similar to that of sample 8. Samples
8 and 7 gave ages of 9.7 and 10.6 Ky, respectively, i.e., an
early Holocene age (Kaakinen et al. 2009).

Late Quaternary foraminiferal record in Murchisonfjorden, Nordaustlandet, Svalbard F. Kubischta et al.

Polar Research 29 2010 283–297 © 2010 the authors, journal compilation © 2010 Blackwell Publishing Ltd290



Assemblage zone A5: Astrononion gallowayi
assemblage (samples 13 and 14)

Description. The sediment consists of a coarsening-
upward sequence of horizontally layered sand and gravel
beds with frequently occurring shell fragments of Hiatella
arctica, Astarte montagui, Astarte borealis and Mya truncata
(unit 8; Figs. 2, 3). Sample 13 was collected from the
lower 30 cm of the sedimentary unit, and sample 14 was
from the middle part. Astrononion gallowayi is the domi-
nant species in both samples, and the most common
accessory species are Cassidulina reniforme (sample 13
only), Cibicides lobatulus, Elphidium albiumbilicatum,
Elphidium hallandense, Elphidium excavatum f. clavata and
Haynesina orbiculare. Compared with the underlying
marine units, assemblage zone A5 is particularly charac-
terized by its high content of Astrononion gallowayi, by the
absence of Islandiella helenae in the lower sample and by a
faunal diversity of 10, which is the highest in the entire
record.

Palaeoenvironment and age. The dominance of
Astrononion gallowayi, particularly in the lower sample,
combined with a relatively high faunal diversity, indicates
a relatively stable salinity and a connection to the open
ocean during deposition. As already mentioned, this
species often occurs in association with Cibicides lobatulus
in high-energy, open-ocean shelf areas, and observations
of high occurrences of Astrononion gallowayi, together
with Cibicides lobatulus and Elphidium albiumbilicatum,
have been reported by Rytter et al. (2002) from near
coastal waters in Iceland. The increase in abundance of
the shallow-water species Elphidium excavatum f. clavata
and Elphidium hallandense, together with Cibicides lobatu-
lus, towards the top of the section coincides with the
coarsening upward of the sediments (see Kaakinen et al.
2009), presumably reflecting an increase in the bottom
current speed and a gradual lowering of the relative sea
level as a result of isostatic rebound. The environmental
indication of the assemblage of sample 14 is not much
different from that of sample 13, but it might reflect a
slight shallowing in water depth. This is in agreement
with the interpretation by Kaakinen et al. (2009) that this
unit was deposited in upper shoreface and littoral envi-
ronments, possibly during a falling sea level caused by
isostatic rebound. Samples 13 and 14 have been dated
at 6.4 and 6.0 Ky, respectively, i.e., mid-Holocene
(Kaakinen et al. 2009).

Correlation and discussion

The foraminiferal assemblages in the Quaternary deposits
from Nordaustlandet are characterized by the dominance

of Arctic taxa, but there is a varying influence of a few
sub-Arctic species that may indicate temporary influence
of slightly warmer water conditions in the area. Gener-
ally, there is a high degree of similarity between the
foraminiferal assemblage zones A1–A5 from Murchison-
fjorden and assemblages described from similar
stratigraphic levels in other areas of Svalbard. Some
variation can be expected, however, partly because of the
poor preservation state of our assemblages and our
unusual laboratory preparation techniques (see above),
and partly because of the influence of different local envi-
ronmental factors. Thus, the number of species and
specimens in the assemblages from Nordaustlandet is
lower than seen at most other sites from the region. This
may be an indication of less favourable conditions in
Nordaustlandet than at the other sites, for instance
caused by the relatively high influence of strong currents
and/or occasional freshwater inflow from glaciers, but it
may also be a result of the poor preservation state of the
samples from Nordaustlandet. However, glacier-proximal
conditions, as characterized by a total dominance of
either Elphidium excavatum f. clavata and/or Cassidulina
reniforme (see Nagy 1965; Hansen & Knudsen 1995;
Korsun et al. 1995; Korsun & Hald 2000), are not
reflected by any of the assemblages from Nordaustlandet.

The correlation of assemblage zones A1–A5 at Isvika,
Nordaustlandet, together with other foraminiferal assem-
blage zones from different sites in Svalbard, are
summarized in Table 3. The following correlations are
mainly focused on Late Quaternary onshore sites in
Svalbard.

Assemblage zones A1 and A2

Assemblage zones A1 and A2 are both referred to the
Early Weichselian. The depositional processes that
formed the specimen-poor assemblage zone A2 are com-
parable with those responsible for the formation of
modern residual assemblages in lag deposits in the
Barents Sea (Østby & Nagy 1981). A comparison with
other Quaternary assemblages is difficult for this kind of
assemblage, and the following correlation is therefore
concentrated on the foraminifera-rich assemblage zone
A1. Generally, the age determinations of Early Weichse-
lian deposits are not accurate enough to distinguish
between different parts of the interval, and a correlation
with assemblage zone A1 would therefore also include
assemblage zone A2.

Shallow marine assemblages from the Poolepynten site
(Fig. 1; Table 3) on Prins Karls Forland (Unit A and Unit
C; Bergsten et al. 1998) contain a similar type of species
composition as found in assemblage zone A1 in Isvika.
Unit A is characterized by a dominance of Cassidulina

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Polar Research 29 2010 283–297 © 2010 the authors, journal compilation © 2010 Blackwell Publishing Ltd 291



reniforme, with Astrononion gallowayi and Elphidium exca-
vatum as the most common accessory species. Astrononion
gallowayi is particularly abundant in the lower part of Unit
A, which is also characterized by a high faunal diversity.
On the basis of the assemblage characteristics, and
supported by amino acid dating, this part of the unit is
considered to be Eemian in age (Bergsten et al. 1998),
whereas the upper part of Unit A and Unit B are referred
to the Early Weichselian. At the transition to unit B, there
is an increase in Elphidium albiumbilicatum and Buccella
frigida, and the composition of this unit is rather close to
assemblage zone A1 at Isvika, although Elphidium albium-
bilicatum is relatively more abundant in assemblage zone
A1.

The inferred ages for units A and C are 80 � 10 and
70 � 10 Ky at Prins Karls Forland, respectively (Bergsten
et al. 1998), corresponding to the ages obtained for
assemblage zone A1 from Isvika (mean age 79 Ky). It has
turned out, however, that OSL ages are often underesti-
mated by 10–14% (Murray & Funder 2003; Murray et al.
2007), and sometimes by even up to 30–50% (Larsen
et al. 2009), and thus there is a possibility that the OSL
ages obtained for the assemblage zones at Isvika may be
too young.

Assemblage zones A1 and A2 correspond in time to
zones FS-I and FS-II at Skilvika, at the mouth of Bellsund
(Lycke et al. 1992) (Fig. 1), and they may also correspond
to assemblage zone FL-IV from Linnéelva, near the
mouth of Isfjorden, western Spitsbergen (Lycke et al.
1992). These assemblages are dominated by Cassidulina

reniforme, Elphidium excavatum and Astrononion gallowayi,
but the species Astrononion gallowayi is relatively more
frequent, and Islandiella helenae and Elphidium albiumbili-
catum are less frequent at Skilvika and Linnéelva than in
assemblage A1 at Isvika. The overall environmental indi-
cation at these sites is, however, much alike, i.e.,
relatively shallow, open marine conditions with some
influence of low-salinity waters, and maybe slightly ame-
liorated temperature conditions. Thermoluminescence
datings from Skilvika gave ages of 89–105 Ky. Dating
results of 87 and 118 Ky B.P. at Linnéelva may indicate a
possible Eemian age for that deposit.

Foraminiferal assemblages in zones F15 IV–F15 I from
Brøggerhalvøya (Miller et al. 1989), further north in
western Spitsbergen (Fig. 1), may correspond in time
with assemblage zones A1 and A2 in Isvika. The general
compositions of the assemblages are similar, but a
detailed correlation is not possible because of the differ-
ence in preservation state, presumably combined with
slightly different local environments (see above). The
age determination for assemblage zones F15 IV–F15 I
(Episode B) from Brøggerhalvøya was 70 � 10 Ky B.P.,
and the deposits are referred to the late part of
MIS 5.

A foraminiferal assemblage found in Early Weichselian
deposits from Kongsfjordhallet on the opposite side of
Kongsfjorden (Fig. 1), with non-finite 14C ages and lumi-
nescence ages of 75 � 10 and 91 � 9 Ky (Sivertsen 1996;
Houmark-Nielsen & Funder 1999), is remarkably similar
to those described in assemblage zone A1 at Isvika.

Table 3 Correlation of the assemblage zones A1–A5 from Isvika, Nordaustlandet, with previously described foraminiferal assemblages from onshore
sections and raised shoreline beach deposits in Svalbard.

Isvika, assemblage

zone (this study) Chrono stratigraphy Locality

Foraminiferal zone/

sedimentary unit Author

A5 Mid-Holocene Kapp Wijk

Talavera

All samples

All samples

Feyling-Hanssen 1955

Feyling-Hanssen 1965

A4 Late Weichselian/Early Holocene Skilvika

Linnéelva

Sarsbukta

Guldalen

Visdalen

Blåfjorddalen

Zone FS-IV

Zone FL-V

Zone QC

Entire record

Entire record

Entire record

Lycke et al. 1992

Lycke et al. 1992

Feyling-Hanssen & Ulleberg 1984

Hansen & Knudsen 1995

Nagy 1984

Landvik et al. 1992

A3 Middle Weichselian (MIS 3) ? Wijdefjorden Region ? Horizon 1 Sharin et al. 2007

A1 and A2 Early Weichselian (MIS 5a–5c) Kongsfjordhallet

Poolepynten

Skilvika

Linnéelva

Brøggerhalvøya

Zone 1304-H;

Succession A

Unit A, upper part; Unit C

Zones FS-I–FS-II

Zone FL-IV

Zones F15 IV–F15 I; Episode B

Sivertsen 1996;

Houmark-Nielsen & Funder 1999

Bergsten et al. 1998

Lycke et al. 1992

Lycke et al. 1992

Miller et al. 1989

? Eemian (MIS 5e) Poolepynten

Sarsbukta

Linnéelva

Unit A, lower part

Zone QB

Zones FL-I–FL-III

Bergsten et al. 1998

Feyling-Hanssen & Ulleberg 1984

Lycke et al. 1992

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Assemblage zone 3

Assemblage zone A3, which is dated to the Middle Weich-
selian, may correspond in time to Horizon 1 described by
Sharin et al. (2007) from the Wijdefjorden region in
Spitsbergen (Fig. 1; Table 3). The assemblage in Horizon 1
is composed of small tests of only 10 species, dominated
by the opportunistic species Elphidium excavatum, and the
horizon appears to have been deposited under unfavour-
able environmental conditions. Unfortunately, Sharin
et al. (2007) do not provide any information on the
detailed faunal composition, and the correlation of
Horizon 1 with the Middle Weichselian Kapp Ekholm
Interstadial (Mangerud & Svendsen 1992) is based solely
on the fact that it is stratigraphically situated below the
Holocene.

The probably Middle Weichselian assemblage from the
Wijdefjorden region (Sharin et al. 2007), which lacks a
proper age control because the age is inferred only on the
basis of its relative stratigraphical position, is the only
previously published description of foraminifera from
onshore records in Svalbard referred to that time interval.
The present description of assemblage zone A3, with
well-constrained OSL and AMS 14C age determinations, is
thus the first description of a well-dated Middle Weich-
selian assemblage in the area.

Assemblage zone 4

Assemblage zone A4 is early Holocene in age and was
deposited shortly after deglaciation. The assemblage is
comparable with the Late Weichselian and early
Holocene zone QC, as described by Feyling-Hanssen &
Ulleberg (1984) from Sarsbukta, Spitsbergen (Fig. 1;
Table 3). There is also a high degree of similarity to the
Late Weichselian and early Holocene assemblages in zone
FS-IV from Skilvika in Bellsund (Lycke et al. 1992),
whereas the underlying zone FS-III from Skilvika
represents a glacier-proximal assemblage with total
dominance by Elphidium excavatum f. clavata. Similar gla-
ciomarine deposits are also found in zone FL-V at
Linnéelva. All these zones are Late Weichselian to early
Holocene in age.

There is a close resemblance between assemblage zone
A4 at Isvika and the foraminiferal species composition in
zones G7A, G7B, G7C, G5A and G5B from Guldalen,
Edgeøya (Hansen & Knudsen 1995), and part of the
marine sequence at Visdalen, Edgeøya (Nagy 1984).
Other foraminiferal zones from Guldalen and Visdalen, as
well as those from Blåfjorddalen, Edgeøya (Landvik et al.
1992), contain different species compositions because of
local differences in the palaeoenvironments.

The palaoenvironmental indications of assemblage
zone A4 (Table 2) is in agreement with the findings of

Mytilus edulis, a species that has been linked with amelio-
rated temperature conditions and slightly reduced salinity
in early Holocene deposits in the Murchisonfjorden area
(Blake 2006).

Assemblage zone 5

Assemblage zone A5 at Isvika corresponds in time to
some rather diverse Holocene assemblages from Tala-
vera, which indicate ameliorated temperature
conditions, and were referred to the Holocene Warm
Interval by Feyling-Hanssen (1965). The environmental
indication of the Isvika assemblages is considerably less
favourable than for the Talavera assemblages, presum-
ably because of the influence of relatively colder water
masses in the Isvika area. The high abundance of
Astrononion gallowayi at both sites is particularly remark-
able. As also pointed out by Bergsten et al. (1998),
similar high abundances as found in the Holocene are
not yet seen in modern foraminiferal faunas. Another
less diverse mid-Holocene fauna has been presented
from shore terraces at Kapp Wijk in Isfjorden by
Feyling-Hanssen (1955a), but at that site, the species
Astrononion gallowayi was not mentioned.

The species composition in assemblage zone A5 is
rather close to that in zone QC from Sarsbukta, which is
rich in Astrononion gallowayi (Feyling-Hanssen & Ulleberg
1984), even though zone QC is Late Weichselian/early
Holocene in age. It is interesting to note that assemblages
from onshore records of Svalbard, which are referred to
the Eemian Interglacial, are often characterized by a high
abundance of Astrononion gallowayi. This is, for instance,
seen for the lower part of Unit A at Poolepynten (Berg-
sten et al. 1998), zone QB at Sarsbukta (Feyling-Hanssen
& Ulleberg 1984) and zones FL-1–FL-3 at Linnéelva
(Lycke et al. 1992).

It is notable that only a few mid-Holocene marine
deposits have been reported from onshore sections of
Svalbard. Data from raised shoreline and beach deposits
with Mytilus edulis, indicating deposition during the
Holocene thermal optimum, are, however, reported from
several sites by Feyling-Hanssen (1955b), Hjort et al.
(1995), Salvigsen (2002) and Blake (2006), among others.

Sea level and glaciations

The timing and palaeoenvironmental interpretations for
assemblage zones A1–A5 (Table 2) from Nordaustlandet
are compared with the eustatic sea-level curve by
Waelbroeck et al. (2002), and with the time–distance
curve for the glaciations in Svalbard by Svendsen et al.
(2004). Although the exact timing of the onset and ter-
mination of Weichselian glaciations in the area is not well

Late Quaternary foraminiferal record in Murchisonfjorden, Nordaustlandet, SvalbardF. Kubischta et al.

Polar Research 29 2010 283–297 © 2010 the authors, journal compilation © 2010 Blackwell Publishing Ltd 293



determined, the marine intervals clearly correlate with
periods of high global sea-level stand during interstadial/
interglacial conditions (Fig. 4).

Koç et al. (2002) state that Hinlopenstretet was
covered by a grounded glacier allowing no water
exchange through the strait during the Late Weichse-
lian. The sea level was around 120 m lower during that
time than at present (Fig. 4; Waelbroeck et al. 2002).
According to Blake (2006), marine waters first entered
Murchisonfjorden at the Younger Dryas–Holocene tran-
sition. This corresponds in time to the first indication of
relatively warm Atlantic Water inflow into Hinlopen-
stretet
from the north (see Koç et al. 2002; Ślubowska et al.
2005; Ślubowska-Woldengen et al. 2007). This inflow,
combined with the increase in insolation (see
Ślubowska et al. 2005), probably resulted in increased
melting of the glaciers on Nordaustlandet, and a subse-
quent large meltwater run-off into the shallow
Murchisonfjorden, as indicated by the foraminiferal
assemblage A4 as well as the occurrence of Mytilus edulis
in the deposits.

Conclusions

This study shows that the coastal area of the north-
western part of Nordaustlandet, Svalbard, was inundated
by the sea (ice free) during at least three, presumably
relatively short, intervals of the Weichselian, as well as
during a major part of the Holocene.

The five Late Quaternary foraminiferal assemblage
zones A1–A5 from Murchisonfjorden, Nordaustlandet, all
represent glacier-distal, inner-shelf environments with
connection to the open ocean, but with some differences
in bottom-current velocity and in salinity (Table 2).

The few foraminiferal samples in the present material
gave a general overview of the environment for each
assemblage zone, but changes within each zone could not
be determined, except for the Holocene. It has not been
possible to pinpoint the exact timing of the samples
within each marine interval of the Weichselian, but they
most likely derive from the middle or late stages of the
interstadials.

Because of high abundances of Arctic species through-
out the Late Quaternary in Svalbard, it is difficult to

Fig. 4 Correlation of the Late Quaternary fora-
miniferal assemblage zones A1–A5 on

Nordaustlandet with the eustatic sea-level

curve of Waelbroeck et al. (2002), the time–

distance curve of the western Barents Sea Ice

Sheet in its northern extension over Svalbard

(Svendsen et al. 2004) and marine isotope

stages (MIS 5–1). Grey shading indicates the

marine intervals in Murchisonfjorden (transi-

tions are graded because the exact timing of

the onset and termination of glaciations in the

area is not well established). Horizontal grey

lines mark the optically stimulated lumines-

cence and accelerator mass spectrometry 14C

mean ages (Ky) of marine samples.

Late Quaternary foraminiferal record in Murchisonfjorden, Nordaustlandet, Svalbard F. Kubischta et al.

Polar Research 29 2010 283–297 © 2010 the authors, journal compilation © 2010 Blackwell Publishing Ltd294



determine if sediments were deposited during an inter-
glacial or an interstadial.

A comparison of assemblage zones A1–A5 from Isvika
with previously described onshore sections and raised
shoreline deposits from the Weichselian and the
Holocene shows that there are some important charac-
teristic features for the assemblages in each of the
stratigraphic intervals in the area, but also that there are
considerable variations as a result of the influence of
different local environmental factors. The marine inter-
vals in Nordaustlandet (assemblage zones A1–A5) clearly
correlate with periods of high global sea-level stand
during interstadial/interglacial conditions.

Acknowledgements

Our thanks go to Dorthe Reng Erbs-Hansen for assistance
with the foraminiferal determinations, to Neil Rees for
improving the language of the paper and to Weston Blake
Jr for reading and commenting on earlier versions of the
manuscript, and for improving the language. We are
grateful to the journal’s subject editor and to the two
reviewers for valuable comments and corrections to the
manuscript. This study was financed by the Academy of
Finland (project no. 1116709), and is a contribution to
the multidisciplinary International Polar Year (IPY) activ-
ity entitled IPY-Kinnvika (IPY 2007-08 project no. 58).

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