Geological Survey of Denmark and Greenland Bulletin 41, 2018, 75-78


75

Initial field activities of the Camp Century Climate  
Monitoring Programme in Greenland

William Colgan, Allan Pedersen, Daniel Binder, Horst Machguth, Jakob Abermann and Mike Jayred

Fig. 1. Location of Camp Century that was constructed by the US Army 
Corps of Engineers in 1959 in the Greenland ice sheet. Camp Century was 
abandonned in 1967.

500 km

Camp Century

Thule Air Base

Camp Century was a military base constructed by the US 
Army Corps of Engineers in 1959 in the near-surface layers 
of the Greenland ice sheet at 77.13°N, 61.03°W and 1886 m 
above sea level (Clark 1965; Fig. 1). The base housed up to 
200 military personel and was continuously occupied until 
1964. After three years of additional seasonal operation, 
the base was abandoned with minimal decommissioning in 
1967. Recent Danish scholarship has documented the politi-
cal and military history of Camp Century in detail (Nielsen 
& Nielsen 2016).
 In 2016, the Geological Survey of Denmark and Green-
land (GEUS) participated in a multi-nation study that pre-
sented regional climate simulations that suggested the ice-
sheet surface mass balance at Camp Century may change 
from net accumulation to net ablation by 2100 under the 
UN Intergovernmental Panel on Climate Change RCP8.5 
‘business-as-usual’ climate scenario. However, according to 
Colgan et al. (2016), net accumulation would persist beyond 
2100 at Camp Century under the climate-change mitigation 
characterised by RCP4.5, an approximately ‘Paris Agree-
ment’ climate scenario.
 In 2017, in response to concerns from the Government of 
Greenland over the potential to remobilisation of contami-
nants from Camp Century within the next century, the Gov-
ernment of Denmark established a programme for long-term 
climate monitoring and detailed one-time surveying of the 
debris field at Camp Century (Colgan et al. 2017). This re-
port describes the initial field activities of the Camp Century 
Climate Monitoring Programme in the context of the four 
programme goals:
1.  To continuously monitor relevant climate variables, in-

cluding the depth to which meltwater percolates, at the 
Camp Century site. 

2.  To regularly update annual likelihoods of meltwater in-
teracting with abandoned materials at the Camp Century 
site over the next century.

3.  To map the estimated spatial extent and vertical depth of 
abandoned wastes across the Camp Century site.

4.  To publicly report all findings from the Camp Century 
Climate Monitoring Programme in a timely manner. 

Field logistics
Field activities of the Camp Century Climate Monitoring 
Programme were initiated in summer 2017, when a six-per-
son team spent two weeks at the Camp Century site (19 July 
to 3 August). There is no abandoned infrastructure visible 
at the ice-sheet surface at Camp Century (Fig. 2). Debris 
field location, as well as zones of restricted drilling depth, 
were estimated prior to field work  (Fig. 3). This was done by 
georeferencing a historical site map using a single tie-point, 
the location of the original drill tower, corrected for motion 
since its last precise survey in 1986 (Gundestrup et al. 1987). 
The 2017 summer camp, which consisted of three common 

© 2018 GEUS. Geological Survey of Denmark and Greenland Bulletin 41, 75–78. Open access: www.geus.dk/bulletin

http://www.geus.dk/bulletin


7676

tents and six personal tents, was established within the debris 
field, approximately aligned with the location of post-closure 
summer camps (Kovacs 1970). Although decamped entirely, 
the footprint of the 2017 summer camp will likely be visible 
in subsequent ice-penetrating radar surveys due to the forma-
tion of massive wind-sculpted snowdrifts around it. 
 During field work, there was persistent cloud cover with 
frequent storm conditions. The mean wind speed was 8.8 
m/s, and the maximum 1 hour mean wind speed was 18.3 m/s 
(Beaufort 8). Thule Air Base, located approximately 200 km 
west, served as logistical base for the field work. A ski-equipped 
Twin Otter aircraft was used to transport 3200 kg of equip-
ment and supplies to and from the ice sheet. Field work con-
sisted of installing three automated instrument stations, drill-
ing boreholes for instrument installation and firn sampling, 
surveying velocity stakes, and collecting ice-penetrating radar 

profiles. Of the 175 m firn core drilled, 135 m were analysed in 
the field and 40 m were transported to Copenhagen for more 
detailed radionuclide analysis by the Center for Nuclear Tech-
nologies at the Technical University of Denmark. 

Instruments and data
Climate measurements were initiated using automated weath-
er station technology previously developed by GEUS. The 
automatic weather station design has a proven record of more 
than 175 station-years of deployment in Greenland since its 
introduction in 2007 (Citterio et al. 2015). The primary 
weather station at Camp Century (CEN) measures air tem-
perature and humidity, wind speed and direction, atmos-
pheric pressure, upward and downward shortwave and long-
wave radiation, subsurface (snow/ice) temperatures to 10 m 

S6
S5

CEN-COM

B62
500 m

B73
CEN

CEN-GPS
CEN-THM

S7
Instrument tower
Borehole
Ice velocity stake
2017 camp
Ice-penetrating radar
25 m drill zone
10 m drill zone

545250 545750 546250 546750 547250 547750 548250

85
66

50
0

85
67

00
0

85
67

50
0

85
68

00
0

85
68

50
0

85
69

00
0

Projection:
WGS84, UTM 20N

S2 S3

S4

Fig. 3. Overview of initial field activities at 
Camp Century. Recently constructed instru-
ment towers refer to the primary weather 
station (‘CEN’), the supplementary thermis-
tor station (CEN-THM), the supplementary 
compaction station (CEN-COM) and the 
supplementary global positioning system station 
(CEN-GPS; to be installed). Boreholes refer 
to the 73 (B73) and 62 (B62) m firn cores. 
Restricted drill zone depths were assessed based 
on georeferencing of a historical as-built site 
map (Kovacs 1970).

Fig. 2. The temporary ice-sheet camp at 1600 
UTC on 20 July 2017. The camp consisted of 
three common tents and six personal tents. There 
was persistent cloud cover with frequent storm 
conditions and a mean wind speed of 8.8 m/s. 
No abandoned infrastructure is visible at the 
ice-sheet surface; the entire debris field is now 
subsurface as a result of net snow accumulation 
since closure. 



77

Fig. 4. Left: Near-surface firn density profiles 
measured both inside (B73) and outside (B62) 
the debris field. The high-density layer between 
32 and 35 m depth within the debris field likely 
ref lects enhanced compaction during the c. 
1960–1964 active period. R ight: Near-surface 
snow/ice temperatures at B73 inside the debris 
field. The annual temperature cycle penetrates to 
c. 12 m depth, with year-round firn temperatures 
remaining c. –24°C below this depth. Density (kg/m  )3

400 600 800

D
ep

th
 (m

)

0

10

20

30

40

50

60

70
B62
B73

Temperature (°C)
–30 –20 –10 0

0

10

20

30

40

50

60

70

Aug

Sep

Oct

Nov

Dec

Jan

Feb

Mar

Apr

depth, and snow depth, as well as diagnostic parameters such 
as battery voltage. The temperature of the relatively porous 
near-surface ice-sheet layer known as firn is also measured by a 
supplementary thermistor station (CEN-THM) to a depth of 
73 m, which approximates local pore close-off depth (Fig. 3). 
 Ice-sheet structure was analysed with 73 and 62 m deep 
firn cores, hereafter referred to as B73 and B62. Firn density 
and melt percentage were measured to a minimum depth of 
62 m at locations inside and outside the debris field (Fig. 4). 
A third automatic station was deployed to measure the com-
paction rate of snow into ice, or vertical strain, over the 0 
to 5 m, 0 to 20 m and 1 to 62 m depth ranges. This third 
automatic station, the supplementary compaction station 
(CEN-COM), is located outside the debris field. All three 
automatic stations satellite-transmit their measurements in 
near-real-time to www.campcenturyclimate.dk. A fourth sta-
tion that records observations from the global positioning 
system (CEN-GPS) will be installed to continuously moni-
tor ice f low. These climate and ice data will be used to cali-
brate and validate future simulations of firn evolution.

Preliminary interpretation
The measurements from the automated weather station 
(CEN) record that midday air temperature exceeded 0°C for 
three days during the operational period of the 2017 summer 
camp. The maximum one-hour mean air temperature was 

1.8°C. Under these warm conditions, surface melt quickly 
froze to moving drill parts when the drill was lowered into 
cold winter firn. This necessitated a two-day suspension of 
drilling. Preliminary analysis of the B73 deep thermistor 
measurements, located within the debris field, indicates that 
the annual temperature cycle in near-surface snow and ice 
temperatures penetrates to c. 12 m depth (Fig. 4). Beyond 
this depth, year-round firn temperatures appear to remain 
c. –24°C. In summer 2017, there was limited meltwater pro-
duction and refreezing, with no apparent change in firn tem-
perature beyond this annual diffusion cycle. 
 Preliminary analysis of near-surface firn structure indi-
cates that refrozen meltwater layers are readily identifiable 
in the uppermost 15 m of the firn. The largest of these lay-
ers is c. 8 cm thick, which represents the melt-and-refreeze of 
c. 25% of annual snowfall (Buchardt et al. 2012). The firn 
cores suggest that meltwater movement beyond the annual 
layer is unlikely. Near-surface firn densities are similar both 
inside and outside the debris field to 32 m depth (Fig. 4). Be-
tween 32 and 35 m depth, firn density is significantly greater 
within the debris field. This high-density layer is slightly dis-
coloured in appearance and likely ref lects enhanced compac-
tion and pollution during the c. 1960–1964 active period. 
Below this active layer, firn densities are similar inside and 
outside the debris field. After drilling B73 through the high-
density active layer, pressurised hydrocarbon vapours vented 
from the borehole until it was backfilled. Mobile hydrocar-

http://www.campcenturyclimate.dk


7878

bon vapours were not anticipated, and vapour-tight equip-
ment was not available on-site to opportunistically sample 
these vapours.

Radar survey
Data from the one-time summer 2017 radar survey are be-
ing analysed to perform a detailed assessment of the hori-
zontal extent and vertical range of the debris field. 100 and 
250 MHz ice-penetrating radar data were collected by cross-
country skiing in a dense grid pattern over the Camp Cen-
tury debris field (Fig. 3). The radar profiles, each tagged with 
global positioning system coordinates, will be available on 
the programme website. A preliminary field analysis of the 
ice-penetrating radar data shows that the sub-surface debris 
field is c. 2 km in diameter, with debris ranging between c. 20 
and 100 m depth. This ice-penetrating radar data will permit 
improved geo-referencing of historical as-built site maps, via 
precisely positioning key subsurface infrastructure features, 
which will facilitate delineating the debris field beyond the 
extent recorded by as-built site maps.

Programme outlook
This report describes the initial field activities of the Camp 
Century Climate Monitoring Programme in the context 
of programme goals. Near-real-time climate and ice meas-
urements from automated stations, ice-penetrating radar 
profiles, as well as programme outreach materials and pub-
lications, can be accessed at www.campcenturyclimate.dk. 
Subsequent field work at Camp Century will be undertaken, 
as needed, to service deployed instrumentation. During these 
subsequent site revisits, ice-velocity stakes will be resurveyed 
to precisely measure the relatively slow (<5 m/yr) ice velocity 
over several years.  
 Data analysis, in support of observationally-constrained 
numerical simulations of the evolution of meltwater and firn, 
is the major programme focus. While climate change now 
gives Camp Century previously unanticipated social signifi-
cance, the sustained effort of the Camp Century Climate 
Monitoring Programme will continue to provide Danish 

and Greenlandic stakeholders open access to relevant in situ 
measurements and model projections. Refined knowledge of 
the spatial extent and vertical range of the debris field, as well 
as the changes in firn structure and meltwater production 
anticipated under climate change, will inform science-based 
discussions of the shifting fate of Camp Century. 

Acknowledgements
The Camp Century Climate Monitoring Programme is jointly funded by 
GEUS and the Danish Cooperation for Environment in the Arctic (DAN-
CEA) within the Danish Ministry for Energ y, Utilities and Climate. J.A. 
was supported by the Greenlandic Ministry of Independence, Foreign 
Affairs and Agriculture. The 2017 field team (W.C., A.P., D.B., H.M., 
J.A. and M.J.) warmly thank Danish liaison officers Kim Marchuard Mik-
kelsen and Jens Alsing for logistical assistance at Thule Air Base.

References
Buchardt, S., Clausen, H., Vinther, B. & Dahl-Jensen, D. 2012: Investigat-

ing the past and recent δ18O-accumulation relationship seen in Green-
land ice cores. Climate of the Past 8, 2053–2059.

Clark, E.F. 1965: Camp Century evolution of concept and history of de-
sign, construction and performance. Cold Regions Research and Engi-
neering Laboratory. Technical Report 174, 69 pp.

Citterio, M. et al. 2015: Automatic weather stations for basic and applied 
glaciological research. Geological Survey of Denmark and Greenland 
Bulletin 33, 69–72.

Colgan, W., Machguth, H., MacFerrin, M., Colgan, J.D., van As, D. & 
MacGregor, J.A. 2016: The abandoned ice sheet base at Camp Cen-
tury, Greenland, in a warming climate. Geophysical Research Letters 
43, 8091–8096.

Colgan, W., Andersen, S.B., van As, D., Box, J.E. & Gregersen, S. 2017: 
New programme for climate monitoring at Camp Century, Greenland. 
Geological Survey of Denmark and Greenland Bulletin 38, 57–60.

Gundestrup, N.S., Clausen, H.B., Hansen, B.L. & Rand, J. 1987: Camp 
century survey 1986. Cold Regions Science and Technolog y 14, 281–
288.

Kovacs, A. 1970: Camp Century a pictorial overview June 1969. Cold Re-
gions Research and Engineering Laboratory, Special Report 150, 59 pp.

Nielsen, H. & Nielsen, K. 2016: Camp Century – cold war city under the 
ice. In: Doel, R., Harper, K. & Heymann, M. (eds): Exploring Green-
land: cold war science and technolog y on ice, 195–216. New York: Pal-
grave Macmillan US.

Authors’ addresses
W.C., A.P., D.B., Geological Survey of Denmark and Greenland, Øster Voldgade 10, DK-1350 Copenhagen K, Denmark. E-mail: wic@geus.dk.
H.M., University of Fribourg, Avenue de l ’Europe 20, SX 1700 Fribourg, Switzerland.
J.A., Asiaq Greenland Survey, Qatserisut 8, DK 3900 Nuuk, Greenland.
M.J., University of Wisconsin, Madison, Wisconsin 53706, USA.

http://www.campcenturyclimate.dk
mailto:wic@geus.dk