A 90-year record of glacier changes in the Novaya Zemlya Archipelago, Russian High Arctic

Dean Maraldo; Woonsup Choi

doi:10.33265/polar.v44.10778

Dean R. Maraldo Department of Geography, University of Wisconsin-Milwaukee, Milwaukee, WI, USA https://orcid.org/0000-0002-0704-786X
Woonsup Choi Department of Geography, University of Wisconsin-Milwaukee, Milwaukee, WI, USA https://orcid.org/0000-0001-5171-2890

DOI: https://doi.org/10.33265/polar.v44.10778

Keywords: Climate change, glacier retreat, satellite imagery, sea-surface temperature

Abstract

Glacial retreat in the Russian High Arctic, particularly in the Novaya Zemlya Archipelago (NZA), is emblematic of global warming. Some global models project that, by 2100, sea-level rise contributions from melting glaciers in this region could be comparable to contributions from Antarctica’s and Greenland’s peripheral glaciers. However, historical glacier change in the NZA remains poorly known. Here, we present the longest decadal chronology of glacier change in the NZA to date, including a 90-year record (ca. 1931–2021) of frontal length change, and a 70-year record (1952–2021) of glacier area change. Using a combination of survey records, historical maps and satellite imagery, we analyse changes for 63 outlet glaciers, representing 86% of the NZA’s total ice mass. Our results show that the average frontal retreat rate increased each decade since the early 1970s, reaching a peak retreat rate of 65 m a^-1 between 2011 and 2021. Glaciers terminating in the Barents Sea experienced the greatest losses, retreating an average of 4.2 km (11.6%) since 1952. During this time, the total glacier area decreased by 1606 km² (10%). We identified increasing summer air and sea-surface temperatures as key drivers of accelerated glacier retreat, with peak air and sea-surface temperatures occurring from 2011 to 2021, corresponding to the period with the fastest retreat rates and the largest glacier area loss.

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References

Bajracharya S.R., Maharjan S.B. & Shrestha F. 2014. The status and decadal change of glaciers in Bhutan from the 1980s to 2010 based on satellite data. Annals of Glaciology 55, 159–166, doi: 10.3189/2014AoG66A125.

Belart J.M.C., Magnússon E., Berthier E., Gunnlaugsson Á.Þ., Pálsson F., Aðalgeirsdóttir G., Jóhannesson T., Thorsteinsson T. & Björnsson H. 2020. Mass balance of 14 Icelandic glaciers, 1945–2017: spatial variations and links with climate. Frontiers in Earth Science 8, article no. 163, doi: 10.3389/feart.2020.00163.

Berner L.T., Massey R., Jantz P., Forbes B.C., Macias-Fauria M., Myers-Smith I., Kumpula T., Gauthier G., Andreu-Hayles L., Gaglioti B.V., Burns P., Zetterberg P., D’Arrigo R. & Goetz S.J. 2020. Summer warming explains widespread but not uniform greening in the Arctic tundra biome. Nature Communications 11, article no. 4621, doi: 10.1038/s41467-020-18479-5.

Black T. & Kurtz D. 2022. Maritime glacier retreat and terminus area change in Kenai Fjords National Park, Alaska, between 1984 and 2021. Journal of Glaciology 69, 251–265, doi: 10.1017/jog.2022.55.

Błaszczyk M., Jania J.A. & Kolondra L. 2013. Fluctuations of tidewater glaciers in Hornsund Fjord (southern Svalbard) since the beginning of the 20th century. Polish Polar Research 34, 327–352, doi: 10.2478/popore-2013-0024.

Carr J.R., Stokes C. & Vieli A. 2014. Recent retreat of major outlet glaciers on Novaya Zemlya, Russian Arctic, influenced by fjord geometry and sea-ice conditions. Journal of Glaciology 60, 155–170, doi: 10.3189/2014JoG13J122.

Carr R., Murphy Z., Nienow P., Jakob L. & Gourmelen N. 2023. Rapid and synchronous response of outlet glaciers to ocean warming on the Barents Sea coast, Novaya Zemlya. Journal of Glaciology, e10, doi: 10.1017/jog.2023.104.

Carrivick J.L. & Tweed F.S. 2013. Proglacial lakes: character, behaviour and geological importance. Quaternary Science Reviews 78, 34–52, doi: 10.1016/j.quascirev.2013.07.028.

Chizov O., Koryakin V., Davidovich N., Kanevsky Z., Singer E., Bazheva V., Bazhev A. & Khmelevskoy I. 1968. Glaciation of the Novaya Zemlya. In: Glaciology IX section of IGY Program 18. P. 338. Moscow: Nauka. (In Russian, with English summary.)

Ciracì E., Velicogna I. & Sutterley T.C. 2018. Mass balance of Novaya Zemlya Archipelago, Russian High Arctic, using time-variable gravity from GRACE and altimetry data from ICESat and CryoSat-2. Remote Sensing 10, article no. 1817, doi: 10.3390/rs10111817.

Fischer M., Huss M., Barboux C. & Hoelzle M. 2014. The new Swiss glacier inventory SGI2010: relevance of using high-resolution source data in areas dominated by very small glaciers. Arctic, Antarctic, and Alpine Research 46, 933–945, doi: 10.1657/1938-4246-46.4.933.

Foss Ø., Maton J., Moholdt G., Schmidt L.S., Sutherland D.A., Fer I., Nilsen F., Kohler J. & Sundfjord A. 2024. Ocean warming drives immediate mass loss from calving glaciers in the High Arctic. Nature Communications 15, article no. 10460, doi: 10.1038/s41467-024-54825-7.

Fox-Kemper B., Hewitt H.T., Xiao C., Aðalgeirsdóttir G., Drijfhout S.S., Edwards T.L., Golledge N.R., Hemer M., Kopp R.E., Krinner G., Mix A., Notz D., Nowicki S., Nurhati I.S., Ruiz L., Sallée J.-B., Slangen A.B.A. & Yu Y. 2021. Ocean, cryosphere, and sea level change. In V. Masson-Delmotte et al. (eds.): Climate change 2021: the physical science basis. Contribution of Working Group I to the sixth assessment report of the Intergovernmental Panel on Climate Change. Pp. 1211–1362. Cambridge: Cambridge University Press.

Gardner A., Moholdt G., Cogley J., Wouters B., Arendt A., Wahr J., Berthier E., Hock R., Pfeffer W., Kaser G., Ligtenberg S., Bolch T., Sharp M., Hagen J., van den Broeke M. & Paul F. 2013. A reconciled estimate of glacier contributions to sea level rise: 2003 to 2009. Science 340, 852–857, doi: 10.1126/science.1234532.

GLIMS & NSIDC 2005. Global Land Ice Measurements from Space glacier database. Compiled and made available by the international GLIMS community and the National Snow and Ice Data Center, Boulder, CO. Accessed on the internet at https://www.glims.org/ on 1 April 2024

Grant K.L., Stokes C.R. & Evans I.S. 2009. Identification and characteristics of surge-type glaciers on Novaya Zemlya, Russian Arctic. Journal of Glaciology 55, 960–972, doi: 10.3189/002214309790794940.

How P., Messerli A., Mätzler E., Santoro M., Wiesmann A., Caduff R., Langley K., Bojesen M.H., Paul F., Kääb A. & Carrivick J.L. 2021. Greenland-wide inventory of ice marginal lakes using a multi-method approach. Scientific Reports 11, article no. 4481, doi: 10.1038/s41598-021-83509-1.

Howat I.M. & Eddy A. 2011. Multi-decadal retreat of Greenland’s marine-terminating glaciers. Journal of Glaciology 57, 389–396, doi: 10.3189/002214311796905631.

Huang B., Thorne P.W., Banzon V.F., Boyer T., Chepurin G., Lawrimore J.H., Menne M.J., Smith T.M., Vose R.S. & Zhang H.-M. 2017. NOAA Extended Reconstructed Sea Surface Temperature (ERSST), version 5. Doi: 10.7289/V5T72FNM. Accessed on the internet at https://psl.noaa.gov/data/gridded/data.noaa.ersst.v5.html on 6 December 2023.

Intergovernmental Panel on Climate Change (IPCC) 2018. Summary for policymakers. In V. Masson-Delmotte et al. (eds.): Global warming of 1.5°C. An IPCC Special Report on the impacts of global warming of 1.5°C above pre-industrial levels and related global greenhouse gas emission pathways, in the context of strengthening the global response to the threat of climate change, sustainable development, and efforts to eradicate poverty. Pp. 3–24. Cambridge: Cambridge University Press.

Kendall M.G. 1955. Rank correlation methods. London: Griffin.

King M.D., Howat I.M., Candela S.G., Noh M.J., Jeong S., Noël B.P.Y., van den Broeke M.R., Wouters B. & Negrete A. 2020. Dynamic ice loss from the Greenland Ice Sheet driven by sustained glacier retreat. Communications Earth & Environment 1, article no. 1, doi: 10.1038/s43247-020-0001-2.

Kjeldsen K.K., Korsgaard N.J., Bjørk A.A., Khan S.A., Box J.E., Funder S., Larsen N.K., Bamber J.L., Colgan W., van den Broeke M., Siggaard-Andersen M.-L., Nuth C., Schomacker A., Andresen C.S., Willerslev E. & Kjær K.H. 2015. Spatial and temporal distribution of mass loss from the Greenland Ice Sheet since AD 1900. Nature 528, 396–400, doi: 10.1038/nature16183.

Kochtitzky W., Copland L., Van Wychen W., Hugonnet R., Hock R., Dowdeswell J.A., Benham T., Strozzi T., Glazovsky A., Lavrentiev I., Rounce D.R., Millan R., Cook A., Dalton A., Jiskoot H., Cooley J., Jania J. & Navarro F. 2022. The unquantified mass loss of Northern Hemisphere marine-terminating glaciers from 2000–2020. Nature Communications 13, article no. 5835, doi: 10.1038/s41467-022-33231-x.

Larocca L.J., Twining–Ward M., Axford Y., Schweinsberg A.D., Larsen S.H., Westergaard–Nielsen A., Luetzenburg G., Briner J.P., Kjeldsen K.K. & Bjørk A.A. 2023. Greenland-wide accelerated retreat of peripheral glaciers in the twenty-first century. Nature Climate Change 13, 1324–1328, doi: 10.1038/s41558-023-01855-6.

Le Bris R. & Paul F. 2013. An automatic method to create flow lines for determination of glacier length: a pilot study with Alaskan glaciers. Computers and Geosciences 52, 234–245, doi: 10.1016/j.cageo.2012.10.014.

Luckman A., Benn D.I., Cottier F., Bevan S., Nilsen F. & Inall M. 2015. Calving rates at tidewater glaciers vary strongly with ocean temperature. Nature Communications 6, article no. 8566, doi: 10.1038/ncomms9566.

Mallalieu J., Carrivick J.L., Quincey D.J. & Smith M.W. 2020. Calving seasonality associated with melt-undercutting and lake ice cover. Geophysical Research Letters 47, e2019GL086561, doi: 10.1029/2019GL086561.

Mann H.B. 1945. Nonparametric tests against trend. Econometrica 13, 245–259, doi: 10.2307/1907187.

Marzeion B., Hock R., Anderson B., Bliss A., Champollion N., Fujita K., Huss M., Immerzeel W.W., Kraaijenbrink P., Malles J.-H., Maussion F., Radić V., Rounce D.R., Sakai A., Shannon S., van de Wal R. & Zekollari H. 2020. Partitioning the uncertainty of ensemble projections of global glacier mass change. Earth’s Future 8, e2019EF001470, doi: 10.1029/2019EF001470.

Melkonian A.K., Willis M.J., Pritchard M.E. & Stewart A.J. 2016. Recent changes in glacier velocities and thinning at Novaya Zemlya. Remote Sensing of Environment 174, 244–257, doi: 10.1016/j.rse.2015.11.001.

Moholdt G., Wouters B. & Gardner A.S. 2012. Recent mass changes of glaciers in the Russian High Arctic. Geophysical Research Letters 39, L10502, doi: 10.1029/2012GL051466.

Noël B., van de Berg W.J., Lhermitte S., Wouters B., Schaffer N. & van den Broeke M.R. 2018. Six decades of glacial mass loss in the Canadian Arctic Archipelago. Journal of Geophysical Research—Earth Surface 123, 1430–1449, doi: 10.1029/2017JF004304.

Nuth C., Kohler J., König M., Von Deschwanden A., Hagen J.O., Kääb A., Moholdt G. & Pettersson R. 2013. Decadal changes from a multi-temporal glacier inventory of Svalbard. Cryosphere 7, 1603–1621, doi: 10.5194/tc-7-1603-2013.

Paul F., Bolch T., Briggs K., Kääb A., McMillan M., McNabb R., Nagler T., Nuth C., Rastner P., Strozzi T. & Wuite J. 2017. Error sources and guidelines for quality assessment of glacier area, elevation change, and velocity products derived from satellite data in the Glaciers_cci project. Remote Sensing of Environment 203, 256–275, doi: 10.1016/j.rse.2017.08.038.

Paul F. & Mölg N. 2014. Hasty retreat of glaciers in northern Patagonia from 1985 to 2011. Journal of Glaciology 60, 1033–1043, doi: 10.3189/2014JoG14J104.

Paul F., Winsvold S., Le Bris R., Scharrer K., Bolch T., Barrand N.E., Frey H., Rastner P., Steffen S., Raup B., Konovalov V., Nosenko G., Joshi S.P., Racoviteanu A., Nuth C., Pope A., Mölg N., Baumann S., Casey K. & Berthier E. 2013. On the accuracy of glacier outlines derived from remote-sensing data. Annals of Glaciology 54, 171–182, doi: 10.3189/2013aog63a296.

Pfeffer W.T., Arendt A.A., Bliss A., Bolch T., Cogley J.G., Gardner A.S., Hagen J.O., Hock R., Kaser G., Kienholz C., Miles E.S., Moholdt G., Mölg N., Paul F., Radić V., Rastner P., Raup B.H., Rich J., Sharp M.J., Andreassen L.M., Bajracharya S., Barrand N.E., Beedle M.J., Berthier E., Bhambri R., Brown I., Burgess D.O., Burgess E.W., Cawkwell F., Chinn T., Copland L., Cullen N.J., Davies B., De Angelis H., Fountain A.G., Frey H., Giffen B.A., Glasser N.F., Gurney S.D., Hagg W., Hall D.K., Haritashya U.K., Hartmann G., Herreid S., Howat I., Jiskoot H., Khromova T.E., Klein A., Kohler J., König M., Kriegel D., Kutuzov S., Lavrentiev I., Le Bris R., Li X., Manley W.F., Mayer C., Menounos B., Mercer A., Mool P., Negrete A., Nosenko G., Nuth C., Osmonov A., Pettersson R., Racoviteanu A., Ranzi R., Sarikaya M.A., Schneider C., Sigurdsson O., Sirguey P., Stokes C.R., Wheate R., Wolken G.J., Wu L.Z. & Wyatt F.R. 2014. The Randolph Glacier Inventory: a globally complete inventory of glaciers. Journal of Glaciology 60, 537–552, doi: 10.3189/2014JoG13J176.

Porter C., Morin P., Howat I., Noh M.-J., Bates B., Peterman K., Keesey S., Schlenk M., Gardiner J., Tomko K., Willis M., Kelleher C., Cloutier M., Husby E., Foga S., Nakamura H., Platson M., Wethington Jr. M., Williamson C., Bauer G., Enos J., Arnold G., Kramer W., Becker P., Doshi A., D’Souza C., Cummens P., Laurier F., Bojesen M. & Foundation N.S. 2018. ArcticDEM Strips, version 3, doi: 10.7910/DVN/OHHUKH.

Racoviteanu A.E., Paul F., Raup B., Jodha S., Khalsa S. & Armstrong R. 2009. Challenges and recommendations in mapping of glacier parameters from space: results of the 2008 Global Land Ice Measurements from Space (GLIMS) workshop, Boulder, Colorado, USA. Annals of Glaciology 50, 53–69, doi: 10.3189/172756410790595804.

Radić V., Bliss A., Beedlow A.C., Hock R., Miles E. & Cogley J.G. 2014. Regional and global projections of twenty-first century glacier mass changes in response to climate scenarios from global climate models. Climate Dynamics 42, 37–58, doi: 10.1007/s00382-013-1719-7.

Rastner P., Strozzi T. & Paul F. 2017. Fusion of multi-source satellite data and DEMs to create a new glacier inventory for Novaya Zemlya. Remote Sensing 9, article no. 1122, doi: 10.3390/rs9111122.

Raup B., Racoviteanu A., Khalsa S.J.S., Helm C., Armstrong R. & Arnaud Y. 2007. The GLIMS geospatial glacier database: a new tool for studying glacier change. Global and Planetary Change 56, 101–110, doi: 10.1016/j.gloplacha.2006.07.018.

Rounce D.R., Hock R., Maussion F., Hugonnet R., Kochtitzky W., Huss M., Berthier E., Brinkerhoff D., Compagno L., Copland L., Farinotti D., Menounos B. & McNabb R.W. 2023. Global glacier change in the 21st century: every increase in temperature matters. Science 379, 78–83, doi: 10.1126/science.abo1324.

Screen J.A. & Simmonds I. 2010. The central role of diminishing sea ice in recent Arctic temperature amplification. Nature 464, 1334–1337, doi: 10.1038/nature09051.

Sharov A.I. 2005. Studying changes of ice coasts in the European Arctic. Geo-Marine Letters 25, 153–166, doi: 10.1007/s00367-004-0197-7.

Smith T.M., Reynolds R.W., Peterson T.C. & Lawrimore J. 2008. Improvements to NOAA’s historical merged land–ocean surface temperature analysis (1880–2006). Journal of Climate 21, 2283–2296, doi: 10.1175/2007JCLI2100.1.

Sommer C., Seehaus T., Glazovsky A. & Braun M.H. 2022. Brief communication: increased glacier mass loss in the Russian Arctic (2010–2017). The Cryosphere 16, 35–42, doi: 10.5194/tc-16-35-2022.

Sun Z., Lee H., Ahn Y., Aierken A., Tseng K.-H., Okeowo M.A. & Shum C.K. 2017. Recent glacier dynamics in the northern Novaya Zemlya observed by multiple geodetic techniques. IEEE Journal of Selected Topics in Applied Earth Observations and Remote Sensing 10, 1290–1302, doi: 10.1109/JSTARS.2016.2643568.

Tape K.D., Christie K., Carroll G. & O’Donnell J.A. 2016. Novel wildlife in the Arctic: the influence of changing riparian ecosystems and shrub habitat expansion on snowshoe hares. Global Change Biology 22, 208–219, doi: 10.1111/gcb.13058.

Tepes P., Nienow P. & Gourmelen N. 2021. Accelerating ice mass loss across Arctic Russia in response to atmospheric warming, sea ice decline, and Atlantification of the Eurasian Arctic shelf seas. Journal of Geophysical Research—Earth Surface 126, e2021JF006068, doi: 10.1029/2021JF006068.

Vaughan D.G., Comiso J.C., Allison I., Carrasco J., Kaser G., Kwok R., Mote P., Murray T., Paul F., Ren J., Rignot E., Solomina O., Steffen K. & Zhang T. 2013. Observations: cryosphere. In T.F. Stocker et al. (eds.): Climate change 2013: the physical science basis. The Working Group I Contribution to the fifth assessment report of the Intergovernmental Panel on Climate Change. Pp. 317–382. Cambridge: Cambridge University Press.

Wijngaard J.B., Klein Tank A.M.G. & Können G.P. 2003. Homogeneity of 20th century European daily temperature and precipitation series. International Journal of Climatology 23, 679–692, doi: 10.1002/joc.906.

Zeeberg J. 2001. Climate and glacial history of the Novaya Zemlya Archipelago, Russian Arctic: with notes on the region’s history of exploration. Amsterdam: Rozenberg Publishers.

Zeeberg J. & Forman S.L. 2001. Changes in glacier extent on north Novaya Zemlya in the twentieth century. The Holocene 11, 161–175, doi: 10.1191/095968301676173261.

Zhang H.-M., Huang B., Lawrimore J., Menne M. & Smith T.M. 2019. NOAA Global Surface Temperature Dataset, version 5.0, doi: 10.25921/9QTH-2P70. National Ocean and Atmospheric Administration National Centers for Environmental Information. Accessed on the internet at https://www.ncei.noaa.gov/products/land-based-station/noaa-global-temp on 1 October 2023.