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PCBs and chlorinated hydrocarbon pesticides in Antarctic atmosphere and hydrosphere
Chemosphere,Vol.12,No.2,pp 277-288,1983 Printed in Great Britain
0045-6535/83/020277-12503.00/0 ©1983 Pergamon Press Ltd.
PCBS AND CHLORINATED HYDROCARBON PESTICIDES IN ANTARCTIC ATMOSPHERE AND HYDROSPHERE Shinsuke Tanabe~ Hideo Hidaka and Ryo Tatsukawa Department of Environment Conservation, Ehime University, Tarumi 3-5-7, Matsuyama 790, Japan Abstract. PCBs and chlorinated hydrocarbon pesticides such as DDTs and HCHs (BHCs) were measured in air, water, ice and snow samples collected around the Japanese research stations in Antarctica and adjacent oceans during December 1980 to March 1982. The atmospheric concentrations of chlorinated hydrocarbons decreased in the transport process from northern lands to Antarctica, but the compositions of PCBs, DDT compounds and HCH isomers were relatively uniform throughout this process. Regional and seasonal variations were found in aerial concentrations of these pollutants at Syowa Station and adjacent seas in Antarctica. Chlorinated hydrocarbons were also detected in snow, ice, lake water and sea water samples, in which rather high concentrations were found in snow and ice samples. This suggests that snow and ice serve as media of supply of these pollutants into Antarctic marine environment. Most interestingly, the concentrations of DDTs and higher chlorinated biphenyls were much lower in sea water under fast ice than in that from outer margin of pack ice. This indicates that the active removal of these pollutants is occurred in the sea under fast ice, and that is strongly associated with high primary productivity. It is, therefore, presumed that the concentrations of PCBs and DDTs in marine organisms living under fast ice in Antarctica could be lower than those in other oceans. i.
INTRODUCTION Studies of the PCB and DDT pollution in Antarctica began with their detec-
tion in the wildlife (Sladen et al., 1966; George and Frear, 1966; Tatton and Ruzicka, 1967; Risebrough et al., 1968) and snow (Peterle, 1969) in the late 1960's.
This finding ensured the worldwide dispersion of these pollutants, and
successively new subjects were generated concerning their transport pathway and entire behavior in the Antarctic environment including atmosphere and hydrosphere. The determination of chlorinated hydrocarbons in Antarctic air and water will contribute to the comprehensive description of their global distribution and also provide basal information for the evaluation of their bioaccumulation in Antarctic ecosystems. The present paper deals with a general pollution of chlorinated hydrocarbons in Antarctic atmosphere and hydrosphere.
In the research, an intensive study has
been made by measuring the concentrations of PCBs, DDT compounds (including p,p'DDE, pjp'-DDT and o,p'-DDT) and HCH (BHC) isomers (including ~, ~ and [ isomers) in air, water, ice and snow samples collected from the Japanese Antarctic research stations and adjacent oceans during December 1980 to March 1982.
Our main con-
cerns are; (i) atmospheric transport process of chlorinated hydrocarbons to Antarctica, (2) regional and seasonal variations of their aerial concentrations in Antarctica, and (3) their behavior indigenous to Antarctic hydrosphere. Recent
277
278
studies
demonstrated
tribution 1981).
Also
which suggests Antarctica.
the
the
over
aerial
gaps.
lands
characteristic
survey,
resulting the
specific
distribution
the
locality
to Antarctica
natural
and behavior
global
1982a,
from northern
variation
amount,
the
with
conditions of these
dis-
o f PCBs, DDTs a n d
(Tanabe et al.,
pollutants
process,
from the
for
Bidleman et al.,
concentrations
Ocean
of these
be extended
transport
and Giam, 1981;
significant
transport
should
In addition,
(Atlas
the Antarctic
transport
aerial
hydrocarbons
use in northern
of atmospheric
hydrocarbons
in air
In this
chlorinated
prevalence
in our previous
HCHs w e r e f o u n d
poral
the
of chlorinated
1982b), lands
to
of airbone
fluxes
and season
of their
some s p a t i a l
in Antarctica
pollutants
of
and temmay i n d u c e
in Antarctic
environment. 2.
SAMPLE Air,
sea water,
lake
water,
ice
a n d snow s a m p l e s
were collected
Syowa Station [69°00'S, 59a55'E) as shown in Fig. i.
around
the
Surface and deep snow were
also sampled at the Mizuho Station (70°42'S, 44°20'E).
Besides land-based sta-
tions in Antarctica,
air and surface water were sampled from the Southern Ocean
on t h e
of research
cruise
routes
Chlorinated the
air
1/min.
pumps. for
the
hydrocarbons Approximately collection
vessels
in air
a s shown i n F i g .
were trapped
1 0 0 0 m3 o f a i r
2.
on p o l y u r e t h a n e
was d r a w n a t
o f PCBs a n d DDT c o m p o u n d s ,
foam by using
a flow rate
and about
of 550-650
200 m3 o f a i r
at
25-27 i/min, for HCH isomers. Sea and lake water under ice sheet were collected by a suction pump. ocean surface water was sampled by a all-metal bucket on board.
Open
Both snow and ice
samples were stocked in airtight polyethylene containers and then melted under room temperature.
About 200 to 1200 1 of water samples were obtained and passed
through Amberlite XAD-2 resin columns. Details of sampling method and discussion of collection efficiency for chlorinated hydrocarbons are given in our previous papers
(Tanabe et at., 1982a,
1982b). 3.
CHEMICAL ANALYSIS Chlorinated hydrocarbons trapped on polyurethane foam and Amberlite XAD-2
resin were eluted with acetone and ethanol respectively.
These solutions were
stocked in tightly sealed glass bottles and shipped to the laboratory. nated hydrocarbons in crude extracts were transferred to hexane.
Chlori-
Hexane solution
was concentrated to 10 ml and then cleaned up by shaking with 5 % fuming sulfuric acid. in
Then, the final hexane extract was further concentrated to 100 21 solution
a microconcentrator under a stream of purified nitrogen gas. Samples were determined by a gas chromatograph-mass
with a selected-ion monitor
spectrometer equipped
(Shimadzu GC-MS 9020 DF) and occasionally analyzed by
an electron-capture gas chromatograph
(Shimadzu GC-SA).
The columns were 2 mm
i.d. x 5 m long and packed with purified Apiezon L grease for PCB determinations,
279
i
I
i
68 ° 55'S-
a Kitano-ura/ Cove
69 °
00'
I
T
90°W ~ . ~
90~/
Syowa Station ~ o
/
180° 05'
i0' Langhovde
0 15'
,
Lake Nurume ~
5 i0 km , , 39°20'E 30' ,, ,,
~"cr~/~-.,~" ~'I ~ , 40' 50'
Figure I. A map showing sample collec tion sites around Syowa Station (69°00'S, 39°35'E), Antarctica.
20°S
, f 40 °
60 °
40°W
0°
40 °
80 °
120 °
160 °
160°E
160°W
Figure 2. Survey cruise routes. [A] anb [B] show the cruise routes of the Icebreaker Fuji during Feb. to Mar. 1982 and the TIS Umitaka-Maru during Dec. 1980 to Feb. 1981 respectively. Air and surface sea water samples were collected along the cruise routes.
280
and 2 mm i.d. x 1.8 m long and packed with 2 % QF-I + 1.5 % OV-17 for DDT compound and HCH isomer determinations. Details of determination procedures and measurement conditions were the same as those reported previously
(Tatsukawa e~ al., 1979).
Contaminations from sampling equipments,
glasswares, adsorbents and solvents
were checked preliminarily and found to be negligible. of PCBs, ZDDT
Overall procedural blanks
(sum of p,p'-DDE, pjp'-DDT and o,p'-DDT) and ZHCH
(sum of ~, ~ and
[ isomers) were less than 2 pg/m 3, 0.I pg/m ~ and 0.5 pg/m 3 for air samples respectively, and less than 5 pg/l, 0.2 pg/l and I pg/l for water samples respectively.
Background levels of aerial chlorinated hydrocarbons in the laboratory
of Syowa Station were also checked and found to be similar to those in outdoor samples. 4.
RESULTS AND DISCUSSION
4. I. Atmospheric Transport to Antarctica In order to make clear the transport pathway and process of chlorinated hydrocarbons to Antarctica, we first described their latitudinal distributions in air over the ocean between Syowa Station and Mauritius (Fig. 3).
The concentra-
tions of atmospheric PCBs, £DDT and £HCH tended to decline toward the Antarctica, although ZHCH was exceptionally high around 61°S latitude.
This declivity sug-
gests that the low latitudes serve as a major source of these pollutants for their transport to Antarctica.
In fact, chlorinated hydrocarbon pesticides such
as DDT and HCH are now consumed mainly in the developing countries in the tropics. Though there is little information on PCB use in the tropical regions, PCBs are most likely to be used in various materials and equipment without any restrictions.
A recent rice bran oil incident in Taiwan (Chen et aZ., 1980, 1981) is an
evidence for the current use of PCBs in the low latitude countries. In contrast to their concentrations,
little variation was found in the com-
positions of HCH isomers, DDT compounds, PCB congeners and its chlorine contents (Fig. 4).
A reasonable explanation for this is already given elsewhere
et al., 1982a, 1982b).
(Tanabe
Extensive use of lindane as well as technical HCH in the
tropics and southern hemisphere accounts for the high proportion of ~ and isomers all over the southern ocean.
Similarity between the composition of
aerial DDT compounds presented here and the formulation of DDT used for agriculture and malaria control suggests the active use of DDT in the tropics.
Abundance
of lower chlorinated biphenyls in open ocean atmosphere may be attributed to their relatively high vapor pressures. In summary, the aerial concentrations of chlorinated hydrocarbons dissipasively decreased in the transport process from northern lands to Antarctica, but their qualitative variations were rather small.
It is well known that chlorinated
hydrocarbons in open ocean atmosphere are present primarily in vapor phase (Giam et al., 1980; Atlas and Giam, 1981; Bidleman et al., 1981; Bidleman and Leonard,
281
1982).
Therefore, the fate and behavior of aerial chlorinated hydrocarbons
depend on the wet deposition and/or the gas exchange at air/sea interface. The uniform composition of aerial chlorinated hydrocarbons found here may imply that the washout rate by rainfall and/or the gas exchange rate at sea surface are almost constant in the world ocean.
3o01 PCBs
°A
......
,,
200
0 rj
h
/\
100
\\
~
20 °
I
I
30 °
40 °
0
0
A
-
0 ~ ~ 0 . I
I
50 °
60 °
O
70°S
Latitude
Figure 3. Latitudinal variations of ZHCH (sum o£ ~, ~ and ~ isomers), ZDDT (sum of pjp'-DDE, pjp'-DDT and ojp'-DDT) and PCB concentrations in open ocean air between Syowa Station (69°00'S, 39°35'E) and Mauritius (20°10'S, S7°30'E).
Latitude
HCH isomer
DDT compound
PCB congener Chlorine 4 5 6 C1 content(%) 45.8
pjp'- pjp'- o,p'68°-69°S
~
o( ~
DDE ~
66°-67°S
~
~
59°-63°S
~
/
[]
~\\\\\~1
54 ° - 6 0 °S
~
~
vA
t.\\\\\\\\~:.:.m
45.3
4 5 o _ .54 o S
~
~
r/,a
t,,\\\\\\\xl:.l
44.1
36°-45oS
~
~
VA
kX\\X~l:.:ll
43,6
27°-36°S
~
~
".'-"
45.8
20°-27°S
~
mr-
V~
k\\\X'l:.:.:ll
i
O
S
|
i
l
[
|
50
'
,
.
•
l
|
100 0
DDT
DDT
2 ~
5
~ W/A
|
i
~ i
i
I
50
.
i
.
t
|
|
100 0
44.1
,
,
•
I
i
50
i
i
i
43.9
44.8
i
100
F i g u r e 4. L a t i t u d i n a l variations o f HCH i s o m e r , DDT compound a n d PCB c o n g e n e r c o m p o s i t i o n s i n o p e n o c e a n a i r b e t w e e n Syowa S t a t i o n a n d M a u r i tius.
282
4.
2. R e g i o n a l Table
cides
and Seasonal
1 shows the
in air
samples
collected
An a p p a r e n t
difference
In general,
higher
(155 ° - 164°E) ration
off
indicate
lands
of these
chemicals
is
seas
the
the
Another
than
in the
Although rather
Recently,
chlorinated
in Arctic,
i n summer t h a n
of snowfall
during
ation
during
cause have
(1982}
less
rations
high
likelihood
in this
of being
Overall, chlorinated of the
it
amount,
a n d on t h e on.
found
reported
Thus,
on l a n d s used
various
and season
that
of Islands.
was a l s o
according
recog-
(Fig.
to the
the austral
seasonal
5).
chemicals, summer.
variation
there
chlorinated 5.
of aerial
in summer,
as well
are
lower
concent-
seasonal
variIn
which might PCBs
but
concent-
still
higher
from the active
factors
amounts
i n same s e a s o n .
on l a n d s
wind,
their
to Antarctica.
evaporation
due to high
and seasonal
on t h e
larger
hydrocarbons
Furthermore,
season,
regional
for
may e x t e n d
atmosphere
use
levels
are
sources
of their
Indian
19801
regions,
aerial
be caused
such as prevailing
the
Balleny
i n Syowa S t a t i o n
particularly
depends
over
to
were apparently
lands
could
mainly
o f PCBs.
variation
during
the
in
and from
concentrations
in a limited
This
case
wind
found
According
concentration
which accounts
in Antarctic
probably
factors
in the
different
period,
can be concluded
locality
natural
Islands)
Coast and near
seasonal
a s shown i n F i g .
from its
hydrocarbons
high
obtained
in northern
applied
i n summer.
o f PCBs i n t o a t m o s p h e r e i n summer s e a s o n .
the
In Antarctic
concentrations
were found
also
in winter.
are
the
i n w h i c h HCH i s o m e r
autumn to winter
pesticides
their
the prevailing
(Tanabe and Tatsukawa,
Sabrina
were slightly
of the use of chemicals
general,
off
hydrocarbons
autumn to winter.
t o be r e m o v e d b y s n o w f a l l rations
explains
seas
use
wind to
hydrocarbons
and Balleny
oceans
were generally
Oehme a n d S t r a y
from
the present
o f DDTs a n d HCHs i n a i r
variation,
patterns
concentrations
levels
may b e p r o b a b l e
aerial
organochlorines higher
however, regional
the varied
high
the
as the
These results
of prevailing
Ocean respectively.
in other
This
over
A PCB c o n c e n t -
hydrocarbons
chlorinated
Coast
Islands
a n d Amundsen Bay) m i g h t b e t r a n s p o r t e d
those
1982).
in air
explanation,
As w e l l
Sabrina
locations.
Balleny
regions.
In Antarctica,
Therefore,
(off
at various
Presumably,
direction
variations.
concentration
much h i g h e r
pesticides
complicated.
pesti-
same s e a s o n .
in Antarctica. in other
chlorinated
and the
Ocean and the Atlantic
Bidleman and Leonard,
nized
these
the year.
Syowa S t a t i o n
Indian
studies,
Ocean are
rather lands
f r o m 121°E t o 164°E
through
these
is
in northern
(off
those
pathway of aerial
to Antarctica
throughout
39°E t o 50°E recent
transport
hydrocarbon the
were found near
(121°-125°E) than
at
was o b s e r v e d
of pesticides
Coast
seem to have led
northwest
the
Sabrina
Atmosphere
locations
concentrations
C o a s t was h i g h e r
the
northern Antarctica
in their
and off
in Antarctic
o f PCBs a n d c h l o r i n a t e d
from different
concentrations
Sabrina
that
Variations
concentrations
variations
of chemicals as their
snowfall,
temperature of aerial inclusive
vapor pressures,
temperature
and so
283
Table i. Regional variations of ZHCH, EDDT and PCB concentrations (pg/m ~) in air samples collected from adjacent seas of Antarctica. Location
Sampling date
EHCH
ZDDT
PCBs
off Sabrina Coast a (61o_65oS, 121o 125oE)
Jan.
'81
120
240
180
near Balleny Islands a (60o_67oS, 155o_164oE)
Jan.
'81
170
190
64
off Syowa Station b (68o_69os, 39oE)
Feb.
'82
49
20
81
near Amundsen Bay b (66oS, 47o_50OE)
Feb.
'82
44
22
96
a Collected by Umitaka-Maru b Collected by Fuji cruise.
cruise.
180 A 160
It
It
J,,..o__
140 .-,
120
O
i00
~
~
/i"',
EHCH
\o
d
80
o u
60
I;
,,
40
/k
,t".-.- -. .
20
/
\ / \ /
~
"
/,
O
40/ °" \ _
\ ?
0
/
A I
~
-O..~lt/"
I
1
I
I
I
I
I
I
I
I
I
I
J '81
F
M
A
M
J
J A Month
S
O
N
D
-A PCBs
I
i
J '82
F
Figure 5. Seasonal variations of ZHCH, ZDDT and PCB concentrations in air collected from Syowa Station, Antarctica.
4. 3. Specific Behavior Concentrations samples are presented concentrations
in A n t a r c t i c
Hydrosphere
o f ZHCH, £DDT a n d PCBs i n s n o w , i c e , in Table
of these
2.
pollutants
p l i e s t h a t snow a n d i c e a c t marine environment. A l t h o u g h a few w o r k e r s
Snow a n d i c e
in comparison with water
as media of s u p p l y of t h e s e so f a r
sea water
samples contained
measured the
and l a k e w a t e r much h i g h e r
samples.
pollutants
concentrations
This
im-
into Antarctic
o f PCBs a n d DDTs
284
Table
2. Concentrations (pg/l) of ZHCH, ZDDT and PCBs in Antarctic lake water and sea water.
Sample Sampling
Snow Mizuho Station ,, Tottuki
Sampling
station
date
snow,
ice,
PCB C1 c o n t . (%)
£HCH
ZDDT
PCBs 160
43.1
(surface) a
May
'81
2300
15
(deep) a
May
'81
1500
9.0
220
42.8
2800
17
160
44.2
4900
16
I000
41.6
2200
Ii
610
40.9
310
41.4
Nov.
Point
'81
Sept.
Lake Nurume Ice Tottuki Point
'81
July-Sept.
'81
Lake Nurume
Nov.
'81
2000
9.8
Sea water b Tottuki Point
July
'81
570
1.3
54
37.9
Oct.
'81
210
1.5
35
38.4
Jan.
'82
570
1.5
69
39.3
Oct.
'82
330
1.3
48
41.2
Langhovde Kitano-ura Cove Lake water b Lake Nurume Sea water c 64°55'S, 124°40'E
Jan.
'81
930
5.4
52
46.4
62°37'S,
157°38'E
Jan.
'81
290
15
42
47.4
62°00'S,
160°06'E
Peb.
'81
290
21
72
46.5
a The age of surface and deep snow were estimated from a report of Watanabe and Yoshimura (1972), and given as 1980 and approximate 1960 respectively. b Collected
from under fast ice.
c Collected
from outer margin of pack ice by Umitaka-Maru
in Antarctic centration the
snow s a m p l e s , levels.
there
r a n g e o f 490 t o 630 p g / k g
300 p g / k g o f PCBs i n s u r f a c e were nearly higher
the
at
hydrocarbon
w h e r e a s LDDT l e v e l s
Syowa S t a t i o n
pollutants
there
was n o t
concentrations.
The m o s t i n t e r e s t i n g
finding
ples,
w h i l e ZDDT c o n c e n t r a t i o n s in surface
water
and
p,p'-DDT)
conwithin
a n d o f 30 t o
Their
PCB l e v e l s were much
a n d d e e p snow s a m p l e s c o l l e c t e d suggests
to Antarctica
since
the
in sea water
load of these
1960's.
comparison of chlorinated
were n o t under
from
in chlorinated
steady
samples under fast
Z HCH c o n c e n t r a t i o n s from outer
difference
that
was made i n t h e
in between sea water
margin of pack ice.
on t h e i r
concentrations
a t Doumer I s l a n d
found any significant This fact
outer
than those
the
and Mizuho S t a t i o n .
surface
has been transported
carbon concentrations
reported
snow s a m p l e s a t Doumer I s l a n d .
In comparison between the Mizuho S t a t i o n ,
r e m a i n some c o n t r a d i c t i o n s (1976)
o f DDTs (sum o f p , p ' - D D E
same o f o u r s ,
than those
still
Risebrough et aZ.
cruise.
fast
ice
and that
so d i f f e r e n t
i n b o t h sam-
i c e were e v i d e n t l y
margin of pack ice.
hydro from lower
PCB c o n c e n t r a t i o n s
285
were nearly at the same level in both samples, but its chlorine contents were apparently lower in under fast ice than in outer margin of pack ice (Table 2). Then, when compared the PCB concentrations in respect of chlorine numbers, much low concentrations were found in higher chlorinated biphenyls in the samples from under fast ice (Table 3).
Moreover, a composition of PCB isomers and congeners
in sea water from under fast ice showed smaller proportion of higher chlorinated biphenyls as compared with those in snow and fast ice which serve as a source of PCB supply into sea water (Fig. 6).
We have noted in a previous paper that less
water soluble chlorinated hydrocarbons with high affinity to suspended materials are readily removed from surface water by sinking particles, and that active removal of these chemicals is strongly associated with the primary productivity in the oceans (Tanabe and Tatsukawa, MS).
Holm-Hansen et aZ. (1977) reported that
the primary productivity in Ross Sea was several times higher in water under fast ice than in water outer margin of pack ice.
These facts, therefore, strongly
support the idea that DDT compounds and higher chlorinated biphenyls with high affinity to suspended materials are rapidly removed from surface to deeper layers in the water column by sinking particles resulting from the active primary productivity under fast ice.
This active vertical transport seems to be responsible
for the low concentrations of these pollutants in sea water under fast ice.
Same
explanation is applicable to water samples from Lake Nurume where both the concentration of £DDT and the chlorine content of PCBs were also low (Table 2). It is well known that DDTs and higher chlorinated biphenyls are very accumulative in the organisms.
The low concentration levels of these pollutants in sea
water under fast ice strongly suggest that DDT and PCB concentrations in marine organisms living under fast ice in Antarctica would be relatively lower than those in other oceans.
Biological studies in Antarctica will appear elsewhere
(Subramanian et al., MS; Hidaka et al., MS).
Table 3. Concentrations (pg/l) of PCEs in respect of chlorine numbers in surface sea water from the Antarctic Ocean. Location 2 C1 5 Cl 4 C1 $ C1 6 Cl Total Under fast ice Tottuki Point
26
21
4.8
1.8
<0.2
54
Langhovde
16
15
4.2
1.3
<0.2
35
Kitano-ura Cove
25
53
9.6
1.4
<0.2
69
5.7
O u t e r margin of pack ice a 64°55'S, 124°40'E
11
17
12
8.2
62°57'S, 157°58'B
8.0
14
II
7.1
1.7
42
62°00'S, 160°06'E
18
26
15
ii
2.3
72
a Collected
by U m i t a k a - M a r u
cruise.
52
286
;now
C1 c o n t e n t :
Sea
44.2
1.0
water
C1 c o n t e n t :
37.9
%
1.0
= 0 U o
> O.S o
IJ,J,,l,,,, |
3l
2
I
.ll
I,III.. II
..
41 s l 6 I 7181g Cl
Fast
0
>0.5
ice
,..,.,
31 41
......
sl
617181~
C1 number
number
CI c o n t e n t :
40.9
1.0
J O u o
>
0.5
I!,'r'1,iJ,,,,,,,,.... 2
31 41 s l
6
17181
CI n u m b e r
Figure 6. PCB isomer and congener compositions in snow, fast ice and sea water samples collected from Tottuki Point near Syowa Station, Antarctica. Sea water was sampled under fast ice. Each bar shows the each peak on mass fragmentogram of PCBs. Details of each peak and its chemical structure are given in our previous report (Tanabe et aZ. 1981).
ACKNOWLEDGEMENTS This study was performed under two projects of the 22nd Japanese Antarctic Research Expedition (JARE-22) and the Biological Investigation of Marine Antarctic Systems and Stocks (BIOMASS).
We are pleased to acknowledge the considerable
support of Professor T. Torii, Chiba Institute of Technology, Dr. T. Hoshiai, National Institute of Polar Research, and Professor T. Yoshida, Tokyo University of Fisheries, for our participation to these projects.
The authors are grateful
to Dr. Y. Yoshida, National Institute of Polar Research, and Professor M. Murano, Tokyo University of Fisheries, for their kind arrangements and encouragements for sampling.
We would like to thank all members of wintering party of JARE-22 and
of BIOHASS project for their advices and cooperations.
Thanks are also due to
the officers and crew of the Icebreaker Fuji and T/S Umitaka-Maru for their assistance on board. This work was supported in part by a Grant-in-Aid for Scientific Research from the Ministry of Education, Science and Culture of Japan.
287
REFERENCES Atlas, E. and C. S. Giam (1981): Global Transport of Organic Pollutants: Ambient Concentrations
in the Remote Marine Atmosphere.
Science, 211, 163-165.
Bidleman, T. F., E. J. Christensen, W. N. Billings and R. Leonard (1981): Atmospheric Transport of Organochlorines Res., 38, 443-469.
in the North Atlantic Gyre.
J. Mar.
Bidleman, T. F. and R. Leonard (1982): Aerial Transport of Pesticides over the Northern Indian Ocean and Adjacent Seas. Atmos. Environ. 18, 1099-1107. Chen, P. H., J. M. Gaw, C. K. Wong and C. J. Chen (1980): Levels and Gas Chromato graphic Patterns of Polychlorinated Biphenyls in the Blood of Patients after PCB Poisoning in Taiwan. Bull. Environ. Contam. Toxicol., 25, 325329.
Chen, P. H., K. T. Chang and Y. D. Lu (1981): Polychlorinated Biphenyls and Polychlorinated Dibenzofurans in the Toxic Rice Bran Oil That Caused PCB Poisoning in Taichung. Bull. Environ. Contam. Toxicol., 26, 489-495. George, J. L. and D. E. H. Frear (1966): Pesticides in the Antarctica. J. Appl. Ecol., 3, 155-167. Giam, C. S., E. Atlas, H. S. Chan and G. S. Neff (1980): Phthalate Esters, PCB and DDT Residues in the Gulf of Mexico Atmosphere. Atmos. Environ., 14, 65-69. Hidaka, H., S. Tanabe and R. Tatsukawa (MS): DDTs and PCBs in Weddell Seals and Their Fate in the Antarctic Marine Ecosystems. Agrlo. Biol. Chem., Holm-Hansen, O., S. Z. Ei-Sayed, G. A. Franceschini and R. L. Cuhel (1977): Primary Production and the Factors Controlling Phytoplanktons Growth in the Southern Oceans. In, Adaptations within Antarctic Ecosystems: Proceeding of the Third SCAR Symposium on Antarctic Biology. Ed. by G. A. Llano, Gulf Publishing Company, Houston, 11-50. Oehme, M. and H. Stray (1982): Quantitative Determination of Ultra-Traces of Chlorinated Compounds in High-Volume Air Samples from the Arctic Using Polyurethane Foam as Collection Medium. Fresen. Anal. Chem., 31, 665-675. Peterle, T. J. (1969): DDT in Antarctic Snow.
Nature, 224, 620.
Risebrough, R. W., P. Riech, D. B. Peakall, S. G. Herman and M. N. Kirven (1968): Polychlorinated Biphenyls in the Global Ecosystem. Nature, 220, 1098-1102 Risebrough, R. W., W. ~. Walker, T. T. Schmidt, B. W. Delappe and C. W. Connors (1976): Transfer of Chlorinated Biphenyls to Antarctica.
Nature, 264, 738
739. Sladen, W. J. L., C. M. Menzie and W. L. Reichei (1966): DDT Residues in Adelie Penguins and a Crabeater Seal from Antarctica. Nature, 210, 670-675. Subramanian, B. R., S. Tanabe, H. Hidaka and R. Tatsukawa (MS): Chlorinated Hydro ~ carbons in Antarctic Fishes. Arch. Environ. Contam. Toxicol.. Tanabe, S. and R. Tatsukawa (1980): Chlorinated Hydrocarbons in the North Pacific and Indian Oceans.
J. Oceanogr. Soc. Japan, 36, 217-226.
288
Tanabe, S., Y. Nakagawa and R. Tatsukawa (1981): Absorption Efficiency and Biological Half-Life of Individual Chlorobiphenyls in Rats Treated with Kanechlor Products. Agric. Biol. Chem., 45, 717-726. Tanabe, S., M. Kawano and R. Tatsukawa (1982a): Chlorinated Hydrocarbons in the Antarctic, Western Pacific and Eastern Indian Oceans. Trans. Tokyo Univ. Fisher., (5), 97-i09. Tanabe, S., R. Tatsukawa, M. Kawano and H. Hidaka (1982b): Global Distribution and Atmospheric Transport of Chlorinated Hydrocarbons: HCH (BHC) Isomers and DDT Compounds in the Western Pacific, Eastern Indian and Antarctic Oceans. J. Oceanogr. Soc. Japan, $8, 157-148. Tanabe, S. and R. Tatsukawa (MS): Vertical Transport and Residence Time of Chlorinated Hydrocarbons in the Open Ocean Water Column. J. Oceanogr. Soc. Japan. Tatsukawa, R., S. Tanabe and T. Yoshida (1979): Man-Made OrEanics. In, Kaiyo Kanky6 Chosah6. Ed. by Oceanogr. Soc. Japan, K6seisha K6seikaku, Tokyo, 252-269 (in Japanese). Tatton, J. O. G. and J. H. A. Ruzicka (1967): OrEanochlorine Pesticides in Antarctica. Nature, 215, 346-348. Watanabe, O. and A. Yoshimura (1972): Glaciological Observations in the Vicinity of Mizuho Camp, Enderby Land, East Antarctica, 1970. (71), 20-52 (in Japanese).
(Received in Japan 8 December 1982)
The Antarctic Record,
0045-6535/83/020277-12503.00/0 ©1983 Pergamon Press Ltd.
PCBS AND CHLORINATED HYDROCARBON PESTICIDES IN ANTARCTIC ATMOSPHERE AND HYDROSPHERE Shinsuke Tanabe~ Hideo Hidaka and Ryo Tatsukawa Department of Environment Conservation, Ehime University, Tarumi 3-5-7, Matsuyama 790, Japan Abstract. PCBs and chlorinated hydrocarbon pesticides such as DDTs and HCHs (BHCs) were measured in air, water, ice and snow samples collected around the Japanese research stations in Antarctica and adjacent oceans during December 1980 to March 1982. The atmospheric concentrations of chlorinated hydrocarbons decreased in the transport process from northern lands to Antarctica, but the compositions of PCBs, DDT compounds and HCH isomers were relatively uniform throughout this process. Regional and seasonal variations were found in aerial concentrations of these pollutants at Syowa Station and adjacent seas in Antarctica. Chlorinated hydrocarbons were also detected in snow, ice, lake water and sea water samples, in which rather high concentrations were found in snow and ice samples. This suggests that snow and ice serve as media of supply of these pollutants into Antarctic marine environment. Most interestingly, the concentrations of DDTs and higher chlorinated biphenyls were much lower in sea water under fast ice than in that from outer margin of pack ice. This indicates that the active removal of these pollutants is occurred in the sea under fast ice, and that is strongly associated with high primary productivity. It is, therefore, presumed that the concentrations of PCBs and DDTs in marine organisms living under fast ice in Antarctica could be lower than those in other oceans. i.
INTRODUCTION Studies of the PCB and DDT pollution in Antarctica began with their detec-
tion in the wildlife (Sladen et al., 1966; George and Frear, 1966; Tatton and Ruzicka, 1967; Risebrough et al., 1968) and snow (Peterle, 1969) in the late 1960's.
This finding ensured the worldwide dispersion of these pollutants, and
successively new subjects were generated concerning their transport pathway and entire behavior in the Antarctic environment including atmosphere and hydrosphere. The determination of chlorinated hydrocarbons in Antarctic air and water will contribute to the comprehensive description of their global distribution and also provide basal information for the evaluation of their bioaccumulation in Antarctic ecosystems. The present paper deals with a general pollution of chlorinated hydrocarbons in Antarctic atmosphere and hydrosphere.
In the research, an intensive study has
been made by measuring the concentrations of PCBs, DDT compounds (including p,p'DDE, pjp'-DDT and o,p'-DDT) and HCH (BHC) isomers (including ~, ~ and [ isomers) in air, water, ice and snow samples collected from the Japanese Antarctic research stations and adjacent oceans during December 1980 to March 1982.
Our main con-
cerns are; (i) atmospheric transport process of chlorinated hydrocarbons to Antarctica, (2) regional and seasonal variations of their aerial concentrations in Antarctica, and (3) their behavior indigenous to Antarctic hydrosphere. Recent
277
278
studies
demonstrated
tribution 1981).
Also
which suggests Antarctica.
the
the
over
aerial
gaps.
lands
characteristic
survey,
resulting the
specific
distribution
the
locality
to Antarctica
natural
and behavior
global
1982a,
from northern
variation
amount,
the
with
conditions of these
dis-
o f PCBs, DDTs a n d
(Tanabe et al.,
pollutants
process,
from the
for
Bidleman et al.,
concentrations
Ocean
of these
be extended
transport
and Giam, 1981;
significant
transport
should
In addition,
(Atlas
the Antarctic
transport
aerial
hydrocarbons
use in northern
of atmospheric
hydrocarbons
in air
In this
chlorinated
prevalence
in our previous
HCHs w e r e f o u n d
poral
the
of chlorinated
1982b), lands
to
of airbone
fluxes
and season
of their
some s p a t i a l
in Antarctica
pollutants
of
and temmay i n d u c e
in Antarctic
environment. 2.
SAMPLE Air,
sea water,
lake
water,
ice
a n d snow s a m p l e s
were collected
Syowa Station [69°00'S, 59a55'E) as shown in Fig. i.
around
the
Surface and deep snow were
also sampled at the Mizuho Station (70°42'S, 44°20'E).
Besides land-based sta-
tions in Antarctica,
air and surface water were sampled from the Southern Ocean
on t h e
of research
cruise
routes
Chlorinated the
air
1/min.
pumps. for
the
hydrocarbons Approximately collection
vessels
in air
a s shown i n F i g .
were trapped
1 0 0 0 m3 o f a i r
2.
on p o l y u r e t h a n e
was d r a w n a t
o f PCBs a n d DDT c o m p o u n d s ,
foam by using
a flow rate
and about
of 550-650
200 m3 o f a i r
at
25-27 i/min, for HCH isomers. Sea and lake water under ice sheet were collected by a suction pump. ocean surface water was sampled by a all-metal bucket on board.
Open
Both snow and ice
samples were stocked in airtight polyethylene containers and then melted under room temperature.
About 200 to 1200 1 of water samples were obtained and passed
through Amberlite XAD-2 resin columns. Details of sampling method and discussion of collection efficiency for chlorinated hydrocarbons are given in our previous papers
(Tanabe et at., 1982a,
1982b). 3.
CHEMICAL ANALYSIS Chlorinated hydrocarbons trapped on polyurethane foam and Amberlite XAD-2
resin were eluted with acetone and ethanol respectively.
These solutions were
stocked in tightly sealed glass bottles and shipped to the laboratory. nated hydrocarbons in crude extracts were transferred to hexane.
Chlori-
Hexane solution
was concentrated to 10 ml and then cleaned up by shaking with 5 % fuming sulfuric acid. in
Then, the final hexane extract was further concentrated to 100 21 solution
a microconcentrator under a stream of purified nitrogen gas. Samples were determined by a gas chromatograph-mass
with a selected-ion monitor
spectrometer equipped
(Shimadzu GC-MS 9020 DF) and occasionally analyzed by
an electron-capture gas chromatograph
(Shimadzu GC-SA).
The columns were 2 mm
i.d. x 5 m long and packed with purified Apiezon L grease for PCB determinations,
279
i
I
i
68 ° 55'S-
a Kitano-ura/ Cove
69 °
00'
I
T
90°W ~ . ~
90~/
Syowa Station ~ o
/
180° 05'
i0' Langhovde
0 15'
,
Lake Nurume ~
5 i0 km , , 39°20'E 30' ,, ,,
~"cr~/~-.,~" ~'I ~ , 40' 50'
Figure I. A map showing sample collec tion sites around Syowa Station (69°00'S, 39°35'E), Antarctica.
20°S
, f 40 °
60 °
40°W
0°
40 °
80 °
120 °
160 °
160°E
160°W
Figure 2. Survey cruise routes. [A] anb [B] show the cruise routes of the Icebreaker Fuji during Feb. to Mar. 1982 and the TIS Umitaka-Maru during Dec. 1980 to Feb. 1981 respectively. Air and surface sea water samples were collected along the cruise routes.
280
and 2 mm i.d. x 1.8 m long and packed with 2 % QF-I + 1.5 % OV-17 for DDT compound and HCH isomer determinations. Details of determination procedures and measurement conditions were the same as those reported previously
(Tatsukawa e~ al., 1979).
Contaminations from sampling equipments,
glasswares, adsorbents and solvents
were checked preliminarily and found to be negligible. of PCBs, ZDDT
Overall procedural blanks
(sum of p,p'-DDE, pjp'-DDT and o,p'-DDT) and ZHCH
(sum of ~, ~ and
[ isomers) were less than 2 pg/m 3, 0.I pg/m ~ and 0.5 pg/m 3 for air samples respectively, and less than 5 pg/l, 0.2 pg/l and I pg/l for water samples respectively.
Background levels of aerial chlorinated hydrocarbons in the laboratory
of Syowa Station were also checked and found to be similar to those in outdoor samples. 4.
RESULTS AND DISCUSSION
4. I. Atmospheric Transport to Antarctica In order to make clear the transport pathway and process of chlorinated hydrocarbons to Antarctica, we first described their latitudinal distributions in air over the ocean between Syowa Station and Mauritius (Fig. 3).
The concentra-
tions of atmospheric PCBs, £DDT and £HCH tended to decline toward the Antarctica, although ZHCH was exceptionally high around 61°S latitude.
This declivity sug-
gests that the low latitudes serve as a major source of these pollutants for their transport to Antarctica.
In fact, chlorinated hydrocarbon pesticides such
as DDT and HCH are now consumed mainly in the developing countries in the tropics. Though there is little information on PCB use in the tropical regions, PCBs are most likely to be used in various materials and equipment without any restrictions.
A recent rice bran oil incident in Taiwan (Chen et aZ., 1980, 1981) is an
evidence for the current use of PCBs in the low latitude countries. In contrast to their concentrations,
little variation was found in the com-
positions of HCH isomers, DDT compounds, PCB congeners and its chlorine contents (Fig. 4).
A reasonable explanation for this is already given elsewhere
et al., 1982a, 1982b).
(Tanabe
Extensive use of lindane as well as technical HCH in the
tropics and southern hemisphere accounts for the high proportion of ~ and isomers all over the southern ocean.
Similarity between the composition of
aerial DDT compounds presented here and the formulation of DDT used for agriculture and malaria control suggests the active use of DDT in the tropics.
Abundance
of lower chlorinated biphenyls in open ocean atmosphere may be attributed to their relatively high vapor pressures. In summary, the aerial concentrations of chlorinated hydrocarbons dissipasively decreased in the transport process from northern lands to Antarctica, but their qualitative variations were rather small.
It is well known that chlorinated
hydrocarbons in open ocean atmosphere are present primarily in vapor phase (Giam et al., 1980; Atlas and Giam, 1981; Bidleman et al., 1981; Bidleman and Leonard,
281
1982).
Therefore, the fate and behavior of aerial chlorinated hydrocarbons
depend on the wet deposition and/or the gas exchange at air/sea interface. The uniform composition of aerial chlorinated hydrocarbons found here may imply that the washout rate by rainfall and/or the gas exchange rate at sea surface are almost constant in the world ocean.
3o01 PCBs
°A
......
,,
200
0 rj
h
/\
100
\\
~
20 °
I
I
30 °
40 °
0
0
A
-
0 ~ ~ 0 . I
I
50 °
60 °
O
70°S
Latitude
Figure 3. Latitudinal variations of ZHCH (sum o£ ~, ~ and ~ isomers), ZDDT (sum of pjp'-DDE, pjp'-DDT and ojp'-DDT) and PCB concentrations in open ocean air between Syowa Station (69°00'S, 39°35'E) and Mauritius (20°10'S, S7°30'E).
Latitude
HCH isomer
DDT compound
PCB congener Chlorine 4 5 6 C1 content(%) 45.8
pjp'- pjp'- o,p'68°-69°S
~
o( ~
DDE ~
66°-67°S
~
~
59°-63°S
~
/
[]
~\\\\\~1
54 ° - 6 0 °S
~
~
vA
t.\\\\\\\\~:.:.m
45.3
4 5 o _ .54 o S
~
~
r/,a
t,,\\\\\\\xl:.l
44.1
36°-45oS
~
~
VA
kX\\X~l:.:ll
43,6
27°-36°S
~
~
".'-"
45.8
20°-27°S
~
mr-
V~
k\\\X'l:.:.:ll
i
O
S
|
i
l
[
|
50
'
,
.
•
l
|
100 0
DDT
DDT
2 ~
5
~ W/A
|
i
~ i
i
I
50
.
i
.
t
|
|
100 0
44.1
,
,
•
I
i
50
i
i
i
43.9
44.8
i
100
F i g u r e 4. L a t i t u d i n a l variations o f HCH i s o m e r , DDT compound a n d PCB c o n g e n e r c o m p o s i t i o n s i n o p e n o c e a n a i r b e t w e e n Syowa S t a t i o n a n d M a u r i tius.
282
4.
2. R e g i o n a l Table
cides
and Seasonal
1 shows the
in air
samples
collected
An a p p a r e n t
difference
In general,
higher
(155 ° - 164°E) ration
off
indicate
lands
of these
chemicals
is
seas
the
the
Another
than
in the
Although rather
Recently,
chlorinated
in Arctic,
i n summer t h a n
of snowfall
during
ation
during
cause have
(1982}
less
rations
high
likelihood
in this
of being
Overall, chlorinated of the
it
amount,
a n d on t h e on.
found
reported
Thus,
on l a n d s used
various
and season
that
of Islands.
was a l s o
according
recog-
(Fig.
to the
the austral
seasonal
5).
chemicals, summer.
variation
there
chlorinated 5.
of aerial
in summer,
as well
are
lower
concent-
seasonal
variIn
which might PCBs
but
concent-
still
higher
from the active
factors
amounts
i n same s e a s o n .
on l a n d s
wind,
their
to Antarctica.
evaporation
due to high
and seasonal
on t h e
larger
hydrocarbons
Furthermore,
season,
regional
for
may e x t e n d
atmosphere
use
levels
are
sources
of their
Indian
19801
regions,
aerial
be caused
such as prevailing
the
Balleny
i n Syowa S t a t i o n
particularly
depends
over
to
were apparently
lands
could
mainly
o f PCBs.
variation
during
the
in
and from
concentrations
in a limited
This
case
wind
found
According
concentration
which accounts
in Antarctic
probably
factors
in the
different
period,
can be concluded
locality
natural
Islands)
Coast and near
seasonal
a s shown i n F i g .
from its
hydrocarbons
high
obtained
in northern
applied
i n summer.
o f PCBs i n t o a t m o s p h e r e i n summer s e a s o n .
the
In Antarctic
concentrations
were found
also
in winter.
are
the
i n w h i c h HCH i s o m e r
autumn to winter
pesticides
their
the prevailing
(Tanabe and Tatsukawa,
Sabrina
were slightly
of the use of chemicals
general,
off
hydrocarbons
autumn to winter.
t o be r e m o v e d b y s n o w f a l l rations
explains
seas
use
wind to
hydrocarbons
and Balleny
oceans
were generally
Oehme a n d S t r a y
from
the present
o f DDTs a n d HCHs i n a i r
variation,
patterns
concentrations
levels
may b e p r o b a b l e
aerial
organochlorines higher
however, regional
the varied
high
the
as the
These results
of prevailing
Ocean respectively.
in other
This
over
A PCB c o n c e n t -
hydrocarbons
chlorinated
Coast
Islands
a n d Amundsen Bay) m i g h t b e t r a n s p o r t e d
those
1982).
in air
explanation,
As w e l l
Sabrina
locations.
Balleny
regions.
In Antarctica,
Therefore,
(off
at various
Presumably,
direction
variations.
concentration
much h i g h e r
pesticides
complicated.
pesti-
same s e a s o n .
in Antarctica. in other
chlorinated
and the
Ocean and the Atlantic
Bidleman and Leonard,
nized
these
the year.
Syowa S t a t i o n
Indian
studies,
Ocean are
rather lands
f r o m 121°E t o 164°E
through
these
is
in northern
(off
those
pathway of aerial
to Antarctica
throughout
39°E t o 50°E recent
transport
hydrocarbon the
were found near
(121°-125°E) than
at
was o b s e r v e d
of pesticides
Coast
seem to have led
northwest
the
Sabrina
Atmosphere
locations
concentrations
C o a s t was h i g h e r
the
northern Antarctica
in their
and off
in Antarctic
o f PCBs a n d c h l o r i n a t e d
from different
concentrations
Sabrina
that
Variations
concentrations
variations
of chemicals as their
snowfall,
temperature of aerial inclusive
vapor pressures,
temperature
and so
283
Table i. Regional variations of ZHCH, EDDT and PCB concentrations (pg/m ~) in air samples collected from adjacent seas of Antarctica. Location
Sampling date
EHCH
ZDDT
PCBs
off Sabrina Coast a (61o_65oS, 121o 125oE)
Jan.
'81
120
240
180
near Balleny Islands a (60o_67oS, 155o_164oE)
Jan.
'81
170
190
64
off Syowa Station b (68o_69os, 39oE)
Feb.
'82
49
20
81
near Amundsen Bay b (66oS, 47o_50OE)
Feb.
'82
44
22
96
a Collected by Umitaka-Maru b Collected by Fuji cruise.
cruise.
180 A 160
It
It
J,,..o__
140 .-,
120
O
i00
~
~
/i"',
EHCH
\o
d
80
o u
60
I;
,,
40
/k
,t".-.- -. .
20
/
\ / \ /
~
"
/,
O
40/ °" \ _
\ ?
0
/
A I
~
-O..~lt/"
I
1
I
I
I
I
I
I
I
I
I
I
J '81
F
M
A
M
J
J A Month
S
O
N
D
-A PCBs
I
i
J '82
F
Figure 5. Seasonal variations of ZHCH, ZDDT and PCB concentrations in air collected from Syowa Station, Antarctica.
4. 3. Specific Behavior Concentrations samples are presented concentrations
in A n t a r c t i c
Hydrosphere
o f ZHCH, £DDT a n d PCBs i n s n o w , i c e , in Table
of these
2.
pollutants
p l i e s t h a t snow a n d i c e a c t marine environment. A l t h o u g h a few w o r k e r s
Snow a n d i c e
in comparison with water
as media of s u p p l y of t h e s e so f a r
sea water
samples contained
measured the
and l a k e w a t e r much h i g h e r
samples.
pollutants
concentrations
This
im-
into Antarctic
o f PCBs a n d DDTs
284
Table
2. Concentrations (pg/l) of ZHCH, ZDDT and PCBs in Antarctic lake water and sea water.
Sample Sampling
Snow Mizuho Station ,, Tottuki
Sampling
station
date
snow,
ice,
PCB C1 c o n t . (%)
£HCH
ZDDT
PCBs 160
43.1
(surface) a
May
'81
2300
15
(deep) a
May
'81
1500
9.0
220
42.8
2800
17
160
44.2
4900
16
I000
41.6
2200
Ii
610
40.9
310
41.4
Nov.
Point
'81
Sept.
Lake Nurume Ice Tottuki Point
'81
July-Sept.
'81
Lake Nurume
Nov.
'81
2000
9.8
Sea water b Tottuki Point
July
'81
570
1.3
54
37.9
Oct.
'81
210
1.5
35
38.4
Jan.
'82
570
1.5
69
39.3
Oct.
'82
330
1.3
48
41.2
Langhovde Kitano-ura Cove Lake water b Lake Nurume Sea water c 64°55'S, 124°40'E
Jan.
'81
930
5.4
52
46.4
62°37'S,
157°38'E
Jan.
'81
290
15
42
47.4
62°00'S,
160°06'E
Peb.
'81
290
21
72
46.5
a The age of surface and deep snow were estimated from a report of Watanabe and Yoshimura (1972), and given as 1980 and approximate 1960 respectively. b Collected
from under fast ice.
c Collected
from outer margin of pack ice by Umitaka-Maru
in Antarctic centration the
snow s a m p l e s , levels.
there
r a n g e o f 490 t o 630 p g / k g
300 p g / k g o f PCBs i n s u r f a c e were nearly higher
the
at
hydrocarbon
w h e r e a s LDDT l e v e l s
Syowa S t a t i o n
pollutants
there
was n o t
concentrations.
The m o s t i n t e r e s t i n g
finding
ples,
w h i l e ZDDT c o n c e n t r a t i o n s in surface
water
and
p,p'-DDT)
conwithin
a n d o f 30 t o
Their
PCB l e v e l s were much
a n d d e e p snow s a m p l e s c o l l e c t e d suggests
to Antarctica
since
the
in sea water
load of these
1960's.
comparison of chlorinated
were n o t under
from
in chlorinated
steady
samples under fast
Z HCH c o n c e n t r a t i o n s from outer
difference
that
was made i n t h e
in between sea water
margin of pack ice.
on t h e i r
concentrations
a t Doumer I s l a n d
found any significant This fact
outer
than those
the
and Mizuho S t a t i o n .
surface
has been transported
carbon concentrations
reported
snow s a m p l e s a t Doumer I s l a n d .
In comparison between the Mizuho S t a t i o n ,
r e m a i n some c o n t r a d i c t i o n s (1976)
o f DDTs (sum o f p , p ' - D D E
same o f o u r s ,
than those
still
Risebrough et aZ.
cruise.
fast
ice
and that
so d i f f e r e n t
i n b o t h sam-
i c e were e v i d e n t l y
margin of pack ice.
hydro from lower
PCB c o n c e n t r a t i o n s
285
were nearly at the same level in both samples, but its chlorine contents were apparently lower in under fast ice than in outer margin of pack ice (Table 2). Then, when compared the PCB concentrations in respect of chlorine numbers, much low concentrations were found in higher chlorinated biphenyls in the samples from under fast ice (Table 3).
Moreover, a composition of PCB isomers and congeners
in sea water from under fast ice showed smaller proportion of higher chlorinated biphenyls as compared with those in snow and fast ice which serve as a source of PCB supply into sea water (Fig. 6).
We have noted in a previous paper that less
water soluble chlorinated hydrocarbons with high affinity to suspended materials are readily removed from surface water by sinking particles, and that active removal of these chemicals is strongly associated with the primary productivity in the oceans (Tanabe and Tatsukawa, MS).
Holm-Hansen et aZ. (1977) reported that
the primary productivity in Ross Sea was several times higher in water under fast ice than in water outer margin of pack ice.
These facts, therefore, strongly
support the idea that DDT compounds and higher chlorinated biphenyls with high affinity to suspended materials are rapidly removed from surface to deeper layers in the water column by sinking particles resulting from the active primary productivity under fast ice.
This active vertical transport seems to be responsible
for the low concentrations of these pollutants in sea water under fast ice.
Same
explanation is applicable to water samples from Lake Nurume where both the concentration of £DDT and the chlorine content of PCBs were also low (Table 2). It is well known that DDTs and higher chlorinated biphenyls are very accumulative in the organisms.
The low concentration levels of these pollutants in sea
water under fast ice strongly suggest that DDT and PCB concentrations in marine organisms living under fast ice in Antarctica would be relatively lower than those in other oceans.
Biological studies in Antarctica will appear elsewhere
(Subramanian et al., MS; Hidaka et al., MS).
Table 3. Concentrations (pg/l) of PCEs in respect of chlorine numbers in surface sea water from the Antarctic Ocean. Location 2 C1 5 Cl 4 C1 $ C1 6 Cl Total Under fast ice Tottuki Point
26
21
4.8
1.8
<0.2
54
Langhovde
16
15
4.2
1.3
<0.2
35
Kitano-ura Cove
25
53
9.6
1.4
<0.2
69
5.7
O u t e r margin of pack ice a 64°55'S, 124°40'E
11
17
12
8.2
62°57'S, 157°58'B
8.0
14
II
7.1
1.7
42
62°00'S, 160°06'E
18
26
15
ii
2.3
72
a Collected
by U m i t a k a - M a r u
cruise.
52
286
;now
C1 c o n t e n t :
Sea
44.2
1.0
water
C1 c o n t e n t :
37.9
%
1.0
= 0 U o
> O.S o
IJ,J,,l,,,, |
3l
2
I
.ll
I,III.. II
..
41 s l 6 I 7181g Cl
Fast
0
>0.5
ice
,..,.,
31 41
......
sl
617181~
C1 number
number
CI c o n t e n t :
40.9
1.0
J O u o
>
0.5
I!,'r'1,iJ,,,,,,,,.... 2
31 41 s l
6
17181
CI n u m b e r
Figure 6. PCB isomer and congener compositions in snow, fast ice and sea water samples collected from Tottuki Point near Syowa Station, Antarctica. Sea water was sampled under fast ice. Each bar shows the each peak on mass fragmentogram of PCBs. Details of each peak and its chemical structure are given in our previous report (Tanabe et aZ. 1981).
ACKNOWLEDGEMENTS This study was performed under two projects of the 22nd Japanese Antarctic Research Expedition (JARE-22) and the Biological Investigation of Marine Antarctic Systems and Stocks (BIOMASS).
We are pleased to acknowledge the considerable
support of Professor T. Torii, Chiba Institute of Technology, Dr. T. Hoshiai, National Institute of Polar Research, and Professor T. Yoshida, Tokyo University of Fisheries, for our participation to these projects.
The authors are grateful
to Dr. Y. Yoshida, National Institute of Polar Research, and Professor M. Murano, Tokyo University of Fisheries, for their kind arrangements and encouragements for sampling.
We would like to thank all members of wintering party of JARE-22 and
of BIOHASS project for their advices and cooperations.
Thanks are also due to
the officers and crew of the Icebreaker Fuji and T/S Umitaka-Maru for their assistance on board. This work was supported in part by a Grant-in-Aid for Scientific Research from the Ministry of Education, Science and Culture of Japan.
287
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(Received in Japan 8 December 1982)
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