Publications

  • 2024
  • Souza-Kasprzyk J., Kozak L., Niedzielski P., 2024: Impacts of anthropogenic activities and glacial processes on the distribution of chemical elements in Billefjord, Svalbard, Arctic. Science of the Total Environment, 909, 168534. DOI: 10.1016/j.scitotenv.2023.168534

  • 2023
  • Kavan J., Luláková P., Małecki J., Strzelecki M.C., 2023: Capturing the transition from marine to land- terminating glacier from the 126-year retreat history of Nordenskiöldbreen, Svalbard. Journal of Glaciology, 1-11. DOI: 10.1017/jog.2023.92.

    Souza-Kasprzyk J., Tkachenko Y., Kozak L., Niedzielski P., 2023: Chemical element distribution in Arctic soils: Assessing vertical, spatial, animal and anthropogenic influences in Elsa and Ebba Valleys, Spitsbergen, Svalbard. Chemosphere, 340, 139862. DOI: 10.1016/j.chemosphere.2023.139862

    Wieczorek I., Strzelecki M.C.,Stachnik Ł., Yde J.C., Małecki J., 2023: Post-LittleIce Age glacial lake evolution in Svalbard: inventory of lake changes and lake types. Journal of Glaciology 1–17. DOI: 10.1017/jog.2023.34.

  • 2022
  • Evans D.J.A., Ewertowski M.W., Roberts D.H., Tomczyk A.M., 2022. The historical emergence of a geometric and sinuous ridge network at the Hørbyebreen polythermal glacier snout, Svalbard and its use in the interpretation of ancient glacial landforms. Geomorphology, 406, 108312, DOI:10.1016/j.geomorph.2022.108213

    Rymer K.G., Rachlewicz G., Buchwal A., Temme A.J.A.M., Reimann T., van der Meij W.M., 2022: Contemporary and past aeolian deposition rates in periglacial conditions (Ebba Valley, central Spitsbergen). CATENA, 211. DOI: 10.1016/j.catena.2021.105974

  • 2021
  • J. Proch, P. Niedzielski, 2021: Multi–mode Sample Introduction System (MSIS) as an interface in the hyphenated system 2 HPLC–MSIS–ICP–OES in simultaneous determination of metals and metalloids species. Analytica Chimica Acta, 1147, 1–14. DOI: 10.1016/j.aca.2020.12.047

    J. Proch, P. Niedzielski, 2021: Iron species determination by high performance liquid chromatography with plasma based optical emission detectors: HPLC–MIP OES and HPLC–ICP OES. Talanta, 231, 122403. DOI: 10.1016/j.talanta.2021.122403

    L. Kozak, J. Souza, A. Nawrot, J. Proch, M. Kaźmierski, A. Zawieja, P. Niedzielski, 2021: Handheld ED–XRF spectrometers in geochemical investigation: Comparative studies for glacial deposits from Spitsbergen, Polish Polar Research, 42(3), 163–172. DOI: 10.24425/ppr.2021.137141

    M. Kugiejko, 2021: Increase of tourist traffic on Spitsbergen: An environmental challenge or chance for progress in the region? Polish Polar Research, 42(2), 139–159. DOI: 10.24425/ppr.2021.136601

    Tomczyk AM., 2021. Morphometry and morphology of fan-shaped landforms in the high-Arctic settings of central Spitsbergen, Svalbard. Geomorphology, 392: 107899 https://doi.org/10.1016/j.geomorph.2021.107899

  • 2020
  • Borysiak J., Pleskot K., Rachlewicz G., 2020: Dryas aeolian landforms in Arctic deflationary tundra, central Spitsbergen. Polish Polar Research, 41, 1, 41-68.

    Ewertowski MW., Tomczyk AM., 2020. Reactivation of temporarily stabilized ice-cored moraines in front of polythermal glaciers: Gravitational mass movements as the most important geomorphological agents for the redistribution of sediments (a case study from Ebbabreen and Ragnarbreen, Svalbard). Geomorphology, 350: 106952, DOI: https://doi.org/10.1016/j.geomorph.2019.106952

    Le Moullec M., Sandal L., Grøtan V., Buchwal A., Hansen B.B. (2020) Climate synchronizes shrub growth across a high-arctic archipelago: contrasting implications of summer and winter warming. Oikos 129(7): 1012-1027. DOI: 10.1111/oik.07059

    Schuler Thomas V., Kohler Jack, Elagina Nelly, Hagen Jon Ove M., Hodson Andrew J., Jania Jacek A., Kääb Andreas M., Luks Bartłomiej, Małecki Jakub, Moholdt Geir, Pohjola Veijo A., Sobota Ireneusz, Van Pelt Ward J. J. (2020) Reconciling Svalbard Glacier Mass Balance. Frontiers in Earth Science, 8, DOI:10.3389/feart.2020.00156

    Storrar RD., Ewertowski M., Tomczyk AM., Barr ID., Livingstone SJ., Ruffell A., Stoker BJ., Evans DJA. 2020. Equifinality and preservation potential of complex eskers. Boreas 49(1):211-231, DOI: https://doi.org/10.1111/bor.12414

    Thomas H.J.D., (…), Buchwal A., (…) (2020) Global plant trait relationships extend to the climatic extremes of the tundra biome. Nature Communications 11, 1351. doi: 10.1038/s41467-020-15014-4

    Thomas V Schuler, Andrey Glazovsky, Jon Ove Hagen, Andrew Hodson, Jacek Jania, Andreas Kääb, Jack Kohler, Bartłomiej Luks, Jakub Malecki, Geir Moholdt, Veijo Pohjola, Ward Van Pelt (2020) New data, new techniques and newchallenges for updating the state of Svalbard glaciers (SvalGlac). SESS Report 2019 – The State of Environmental Science in Svalbard.

  • 2019
  • Buchwal A., Weijers S., Blok D., Elberling B., 2019: Temperature sensitivity of willow dwarf shrub growth from two distinct High Arctic sites. International Journal of Biometeorology, 63(2), 167-181; doi: 10.1007/s00484-018-1648-6

    Ewertowski M. W., Evans D. J. A., Roberts D. H., Tomczyk A. M., Pleskot K., Ewertowski W., 2019: Quantification of historical landscape change on the foreland of a receding polythermal glacier, Hørbyebreen, Svalbard. Geomorphology, 325, 50-54; doi:10.1016/j.geomorph.2018.09.027

    Ewertowski M. W., Tomczyk A. M., Evans D. J. A, Roberts D. H, Ewertowski W., 2019: Operational framework for rapid, very-high resolution mapping of glacial geomorphology using low-cost Unmanned Aerial Vehicles and Structure-from-Motion approach. Remote Sensing 11, 65; doi: 10.3390/rs11010065

    Ewertowski M. W., Tomczyk A. M., 2020: Reactivation of temporarily stabilized ice-cored moraines in front of polythermal glaciers: Gravitational mass movements as the most important geomorphological agents for the redistribution of sediments (a case study from Ebbabreen and Ragnarbreen, Svalbard). Geomorphology, 350, 106952; doi: https://doi.org/10.1016/j.geomorph.2019.106952

    Małecki J., 2019: Meteorology and summer net radiation of an Arctic alpine glacier: Svenbreen, Svalbard. International Journal of Climatology, 39, 10, 4107-4124; doi: 10.1002/joc.6062

    Przybylak R., Araźny A., Miętus M., Migała K., Niedźwiedź T., Rachlewicz G., Siwek K., Ustrnul Z., 2019: Polskie badania polarne z zakresu meteorologii i klimatologii. Przegląd Geofizyczny, LXIV, 1-2, 3-33

    Thomas H.J.D., Myers-Smith I.H., Bjorkman A.D., Elmendorf S.C., Blok D., Cornelissen J.H.C., Forbes B.C., Hollister R., Normand S., Prevey J.S., Rixen C., Schaepman-Strub G., Wilmking M., Wipf S., Cornwell W., Kattge J., Goetz S., Guay K., Alatalo J., Anadon Rosell A., Angers-Blondin S., Berner L.T., Björk R.G., Buchwal A., Buras A., Carbognani M., Christie K., Collier L.S., Cooper E.J., Eskelinen A., Frei E.R., Grau O., Grogan P., Hallinger M., Heijman M.M.P.D., Hermanutz L., Hudson J.M.G., Hülber K., Iturrate-Garcia M., Iversen C.M., Jaroszynska F., Johnstone J., Kaarlejarvi E., Kulonen A., Lamarque L., Levesque E., Little C.J., Michelsen A., Milbau A., Nabe-Nielsen J., Nielsen S.S., Ninot J.M., Oberbauer S., Olofsson J., Onipchenko V., Petraglia A., Rumpf S.B., Semenchuk P.R., Soudzilovskaia N., Spasojevic M., Speed J.D.M., Tape K., Te Beest M., Tomaselli M., Trant A., Treier U., Venn S., Vowles T., Weijers S., Zamin T., Atkin O., Bahn M., Blonder B., Campetella G., Cerabolini B.E.L., Chapin F.S., Dainese M., De Vries F.T., Diaz S., Green W., Jackson R., Manning P., Niinemets Ü., Ozinga W.A., Penuelas J., Reich P., Schamp B., Sheremetev S., van Bodegom P.M., 2019: Traditional plant functional groups explain variation in economic but not size-related traits across the tundra biome. Global Ecology and Biogeography, 28, 78-95; doi.org/10.1111/geb.12783

    Tomczyk A. M., Ewertowski M. W., Stawska M., Rachlewicz G., 2019 – Detailed alluvial fan geomorphology in a high-arctic periglacial environment, Svalbard: application of unmanned aerial vehicle (UAV) surveys. Journal of Maps, 15,2, 460-473; doi: 10.1080/17445647.2019.1611498

    Zawierucha K., Baccolo G., Di Mauro B., Nawrot A., Szczucinski W., Kalinska E., 2019: Micromorphological features of mineral matter from cryoconite holes on Arctic (Svalbard) and alpine (the Alps, the Caucasus) glaciers. Polar Science, in press; doi.org/10.1016/j.polar.2019.100482

  • 2018
  • Bjorkman A. D., Myers-Smith I. H., Elmendorf S. C., Normand S., Rüger N., Beck P. S. A., Blach-Overgaard A., Blok D., Cornelissen J. H. C., Forbes B. C., Georges D., Goetz S. J., Guay K. C., Henry G. H. R., HilleRisLambers J., Hollister R. D., Karger D. N., Kattge J., Manning P., Prevéy J. S., Rixen C., Schaepman-Strub G., Thomas H. J. D., Vellend M., Wilmking M., Wipf S., Carbognani M., Hermanutz L., Lévesque E., Molau U., Petraglia A., Soudzilovskaia N. A., Spasojevic M. J., Tomaselli M., Vowles T., Alatalo J. M., Alexander H. D., Anadon-Rosell A., Angers-Blondin S., te Beest M., Berner L., Björk R. G., Buchwał A., Buras A., Christie K., Cooper E. J., Dullinger S., Elberling B., Eskelinen A., Frei E. R., Grau O., Grogan P., Hallinger M., Harper K. A., Heijmans M. M. P. D., Hudson J., Hülber K., Iturrate-Garcia M., Iversen C. M., Jaroszynska F., Johnstone J. F., Jørgensen R. H., Kaarlejärvi E., Klady R., Kuleza S., Kulonen A., Lamarque L. J., Lantz T., Little C. J., Speed J. D. M., Michelsen A., Milbau A., Nabe-Nielsen J., Nielsen S. S., Ninot J. M., Oberbauer S. F., Olofsson J., Onipchenko V. G., Rumpf S. B., Semenchuk P., Shetti R., Siegwart Collier L., Street L. E., Suding K. N., Tape K. D., Trant A., Treier U. A., Tremblay J. P., Tremblay M., Venn S., Weijers S., Zamin T., Boulanger-Lapointe N., Gould W. A., Hik D. S., Hofgaard A., Jónsdóttir I. S., Jorgenson J., Klein J., Magnusson B., Tweedie C., Wookey P. A., Bahn M., Blonder B., van Bodegom P. M., Bond-Lamberty B., Campetella G., Cerabolini B. E. L., Chapin III F. S., Cornwell W. K., Craine J., Dainese M., de Vries F. T., Díaz S., Enquist B. J., Green W., Milla R., Niinemets Ü., Onoda Y., Ordoñez J. C., Ozinga W. A., Penuelas J., Poorter H., Poschlod P., Reich P. B., Sandel B., Schamp B., Sheremetev S., Weiher E., 2018: Plant functional traits change across a warming tundra biome. Nature 562, 57-62. https://www.nature.com/articles/s41586-018-0563-7

    Bjorkman A. D., Myers-Smith I. H., Elmendorf S. C., Normand S., Thomas H. J. D., Alatalo J. M., Alexander H., Anadon Rosell A., Angers-Blondin S., Bai Y., Baruah G., te Beest M., Berner L., Björk R. G., Blok D., Bruelheide H., Buchwał A., Buras A., Carbognani M., Christie K., Collier L. S., Cooper E. J., Cornelissen J. H. C., Dickinson K. J. M., Dullinger S., Elberling B., Eskelinen A., Forbes B. C., Frei E. R., Iturrate-Garcia M., Good M. K., Grau O., Green P., Greve M., Grogan P., Haider S., Hajek T., Hallinger M., Happonen K., Harper K. A., Heijmans M. M. P. D., Henry G. H. R., Hermanutz L., Hollister R. D., Hudson J., Hülber K., Iversen C. M., Jaroszynska F., Jiménez‐Alfaro B., Johnstone J., Jorgensen R. H., Kaarlejarvi E., Klady R., Klimesova J., Korsten A., Kuleza S., Kulonen A., Lamarque L. J., Lantz T., Lavallee A., Lembrechts J. J., Levesque E., Little C. J., Luoto M., Macek P., Mack M. C., Mathakutha R., Michelsen A., Milbau A., Molau U., Morgan J. W., Mörsdorf M. A., Nabe-Nielsen J., Nielsen S. S., Ninot J. M., Oberbauer S., Olofsson J., Onipchenko V. G., Petraglia A., Pickering C., Prevey J. S., Rixen C., Rumpf S. B., Schaepman-Strub G., Semenchuk P., Shetti R., Soudzilovskaia N. A., Spasojevic M. J., Speed J. D. M., Street L., Suding K., Tape K. D., Tomaselli M., Trant A., Treier U. A., Tremblay J. P., Tremblay M., Venn S., Virkkala A. M., Vowles T., Weijers S., Wilmking M., Wipf S., Zamin T., 2018: Tundra Trait Team: A database of plant traits spanning the tundra biome. Global Ecology and Biogeography 27, 12,1402-1411. https://onlinelibrary.wiley.com/doi/full/10.1111/geb.12821

    Buchwał A., Weijers S., Blok D., Elberling B., 2018: Temperature sensitivity of willow dwarf shrub growth from two distinct High Arctic sites. International Journal of Biometeorology. https://link.springer.com/article/10.1007/s00484-018-1648-6

    Ewertowski M., Evans D. J. A., Roberts D. H., Tomczyk A. M., Ewertowski W., Pleksot K., 2019: Quantification of historical landscape change on the foreland of a receding polythermal glacier, Hørbyebreen, Svalbard. Geomorphology 325, 40–54.

    Kendzierski S., 2017: Porównanie przebiegu temperatury powietrza i wilgotności względnej w Petuniabukta i Svalbard-Lufthavn (Spitsbergen) w sezonie letnim 2016. Badania Fizjograficzne 68, 19-31.

    Kendzierski S., Kolendowicz L., Półrolniczak M., 2018. The influence of synoptic condition patterns on air temperature and humidity in Petuniabukta (Svalbard) in summer 2018. Polish Polar Research 39, 3, 371–392.

    Strzelecki M. Cz., Long A. J., Lloyd J. M., Małecki J., Zagórski P., Pawłowski Ł, Jaskólski M. W., 2018: The role of rapid glacier retreat and landscape transformation in controlling the post-Little Ice Age evolution of paraglacial coasts in central Spitsbergen (Billefjorden, Svalbard). Land Degradation and Development, 29, 6, 1962-1978.

    Thomas H. J. D., Myers-Smith I. H., Bjorkman A. D., Elmendorf S. C., Blok D., Cornelissen J. H. C., Forbes B. C., Hollister R., Normand S., Prevey J. S., Rixen C., Schaepman-Strub G., Wilmking M., Wipf S., Cornwell W., Kattge J., Goetz S., Guay K., Alatalo J., Anadon Rosell A., Angers-Blondin S., Berner L. T., Björk R. G., Buchwał A., Buras A., Carbognani M., Christie K., Collier L. S., Cooper E. J., Eskelinen A., Frei E. R., Grau O., Grogan P., Hallinger M., Heijman M. M. P. D., Hermanutz L., Hudson J. M. G., Hülber K., Iturrate-Garcia M., Iversen C. M., Jaroszynska F., Johnstone J., Kaarlejarvi E., Kulonen A., Lamarque L., Levesque E., Little C. J., Michelsen A., Milbau A., Nabe-Nielsen J., Nielsen S. S., Ninot J. M., Oberbauer S., Olofsson J., Onipchenko V., Petraglia A., Rumpf S. B., Semenchuk P. R., Soudzilovskaia N., Spasojevic M., Speed J. D. M., Tape K., Te Beest M., Tomaselli M., Trant A., Treier U., Venn S., Vowles T., Weijers S., Zamin T., Atkin O., Bahn M., Blonder B., Campetella G., Cerabolini B. E. L., Chapin F. S., Dainese M., De Vries F. T., Diaz S., Green W., Jackson R., Manning P., Niinemets Ü., Ozinga W. A., Penuelas J., Reich P., Schamp B., Sheremetev S., van Bodegom P. M., 2018: Traditional plant functional groups explain variation in economic but not size-related traits across the tundra biome. Global Ecology and Biogeography. https://onlinelibrary.wiley.com/doi/epdf/10.1111/geb.12783

    Rachlewicz G. (red.), 2017: Cryosphere reactions against the background of environmental changes in contrasting high-Arctic conditions in Svalbard. Institute of Geoecology and Geoinformation, A. Mickiewicz University in Poznań Polar Reports, vol. 2, Bogucki Wydawnictwo Naukowe.

  • Other:
  • Bednorz E. i Kolendowicz L. 2010: Summer 2009 thermal and bioclimatic conditions in the Ebba Valley region. Polish Polar Research 31/4, 327-348. DOI: 10.2478/v10183-010-0009-x

    Borysiak J., Pleskot K., Rachlewicz G., 2020: Dryas aeolian landforms in Arctic deflationary tundra, central Spitsbergen. Polish Polar Research, 41, 1, 41-68. DOI: 10.24425/ppr.2020.132569

    Buchwał A., 2008: Funkcjonowanie dróg w górskim systemie stokowym masywu Pyramiden na Spitsbergenie. Prace geograficzne UJ, 120, 9-17.

    Buchwal A., Rachlewicz G., Fonti P., Cherubini P. i Gaertner H., 2013: Temperature modulates intra-plant growth of Salix polaris from a high Arctic site (Svalbard). Polar Biology, 36, 9, 1305-1318. DOI: 10.1007/s00300-013-1349-x.

    Choiński A., 1989: Hydrology of the mouth section of the Ebbaelva and the Petuniabukta, Billefjorden, central Spitsbergen. Polish Polar Res., 10(3), 457-464.

    Dragon K. i Marciniak M., 2010: Chemical composition of groundwater and surface water in the Arctic environment (Petuniabukta region, central Spitsbergen). Journal of Hydrology, 386, 160-172.Gibas J., Rachlewicz G. i Szczuciński W. 2005. Application of DC resistivity soundings and geomorphological surveys in studies of modern Arctic glacier marginal zones, Petuniabukta, Spitsbergen. Pol. Polar Res, 26(4), 239-258.

    Gulińska J., Rachlewicz G., Szczuciński W., Barałkiewicz D., Kózka M., Bulska E. i Burzyk M., 2003: Soil Contamination in High Arctic Areas of Human Impact, Central Spitsbergen, Svalbard. Pol. J. Environ. Stud., 12(6), 701-707.

    Małecki J., 2013: Sven Glacier in central Spitsbergen ? current state as reaction to changes after Little Ice Age. Praca doktorska. Instytut Geoekologii i Geoinformacji, UAM, Poznań.

    Małecki J., Buchwał A., Rachlewicz G., Rymer K., Strzelecki M. i Wawrzyniak T., 2011: Environmental studies in northern Billefjorden - Institute of Geoecology and Geoinformation A. Mickiewicz University 15th Expedition - Svalbard 2010. [w:] G. Rachlewicz, J. Małecki (red.), Institute of Geoecology and Geoinformation A. Mickiewicz University Polar Reports. Vol. 1. Bogucki Wydawnictwo Naukowe, Poznań.

    Marciniak M. i Dragon K., 2010: The influence of ground-water discharge on the runoff of an Arctic stream (Ebba River, central Spitsbergen). Biuletyn Państwowego Instytutu Geologicznego, 441, 93-100.

    Mazurek M., Paluszkiewicz R., Rachlewicz G. i Zwoliński Z., 2012: Variability of water chemistry in tundra lakes, Petuniabukta coast, central Spitsbergen, Svalbard. The Scientific World Journal, Article ID 596516: 1-13. DOI: 10.1100/2012/596516.

    Karczewski A., 1989: The development of the marginal zone of the H?rbyebreen, central Spitsbergen. Pol. Polar Res., 10(3), 371-377.

    Karczewski A. (red.), Borówka M., Gonera P., Kasprzak L., Kłysz P., Kostrzewski A., Lindner L., Marks L., Rygielski W., Stankowski W., Wojciechowski A. i Wysokiński L., 1990: Geomorphology - Petuniabukta, Billefjorden, Spitsbergen, 1:40 000. Uniwersytet im. A. Mickiewicza, Poznań.

    Kłysz P., 1985: Glacial forms and deposits of Ebba Glacier and its foreland (Petuniabukta region, Spitsbergen). Polish Polar Research, 6, 3, 283-299.

    Kłysz P., Lindner L., Marks L. i Wysokiński L., 1989: Late Pleistocene and Holocene relief remodeling in the Ebbadalen?Nordenkiöldbreen region in Olav V Land, central Spitsbergen. Pol. Polar Res., 10(3), 277?301.

    Kostrzewski A., Kapuściński J., Klimczak R., Kaniecki A., Stach A. i Zwoliński Z., 1989: The dynamics and rate of denudation of glaciated and non-glaciated catchments, central Spitsbergen. Pol. Polar Res., 10(3), 317-367.

    Kostrzewski A. i Zwoliński Z. (red.), 2007: Geodiversity of polar landforms. Landform Analysis, vol. 5, 220 p.

    Long A. J., Strzelecki M. C., Lloyd J. M., Bryant C., 2012: Dating High Arctic Holocene relative sea level changes using juvenile articulated marine shells in raised beaches. Quaternary Science Reviews, 48 (2012), 61-66.

    Rachlewicz G., 2003: Warunki meteorologiczne w Zatoce Petunia (Spitsbergen Środkowy), w sezonach letnich 2000-2001. Probl. Klim. Pol., 13, 127-138.

    Rachlewicz G., 2004: Pomiary ruchu lodowców w otoczeniu Petuniabukta ? Billefjorden (Spitsbergen Środkowy). XXX Międzynarodowe Sympozjum Polarne, streszczenia wystąpień, Gdynia: 149.

    Rachlewicz G., 2004: Pomiary ruchu lodowców w otoczeniu Petuniabukta ? Billefjorden (Spitsbergen Środkowy). XXX Międzynarodowe Sympozjum Polarne, streszczenia wystąpień, Gdynia: 149.

    Rachlewicz G., 2009: Contemporary sediment fluxes and relief changes in high Arctic glacierized valley systems (Billefjorden, Central Spitsbergen). Wyd. Nauk. UAM, Geografia, 87, Poznań. (PDF) (ZAŁĄCZNIK)

    Rachlewicz G., 2010: Paraglacial modifications of glacial sediments over millennial to decadal time-scales in the high Arctic (Billefjorden, central Spitsbergen, Svalbard). Quaestiones Geographicae, 29(3), 59-67.

    Rachlewicz G. i Styszyńska A., 2007: Porównanie przebiegu temperatury powietrza w Petuniabukta i Svalbard-Lufthavn (Isfjord, West Spitsbergen) w latach 2001-2003. Probl. Klim. Polarnej, 17, 121-134.

    Rachlewicz G. i Szczuciński W., 2008: Changes in permafrost active layer thermal structure in relation to meteorological conditions, Petuniabukta, Svalbard. Polish Polar Res., 28(3), 261-278.

    Rachlewicz G., Szczuciński W. i Ewertowski M., 2007: Post??Little Ice Age? retreat rates of glaciers around Billefjorden in central Spitsbergen, Svalbard. Polish Polar Res., 28(3), 159-186.

    Rachlewicz G., Baran J. i Pleskot K., 2013: Rozwój turystyki w obszarach polarnych na przykładzie Svalbardu. Prace Państwowej Wyższej Szkoły Zawodowej w Gorzowie.

    Rygielski W., Rachlewicz G. i Sprutta M., 1988: Formy wietrzenia chemicznego konglomeratów wapiennych, Olaf V Land, Spitsbergen. Mat. XV Symp. Pol., Wrocław, 61-65.

    Rymer K., 2012: Permafrost active layer temperature variationa in Ebba Valley (central Spitsbergen) in the years 2009-2012. Polar Ecology Conference, Česke Budejovice, 97.

    Rymer K. i Rachlewicz G., 2014: Thermal dynamics of the permafrost active layer in Ebba valley (central Spitsbergen) in the years 2009-2012. International Journal of Applied and Natural Sciences, 3, 3, 79-86.

    Stankowski W. (red.), 1989: Quaternary paleogeography and present-day processes in an area between Billefjorden and Austfjorden, central Spitsbergen. Polish Polar Research, 10(3), 1-475.

    Stankowski W., Kasprzak L., Kostrzewski A. i Rygielski W., 1989: An outline of morphogenesis of the region between H?rbyedalen and Ebbadalen, Petuniabukta, Billefjorden, central Spitsbergen. Polish Polar Res., 10(3), 267-276.

    Szpikowski J., Szpikowska G., Zwoliński Z., Rachlewicz G., Kostrzewski A., Marciniak M. i Dragon K., 2014: Character and rate of denudation in a High Arctic glacierized catchment (Ebbaelva, Central Spitsbergen). Geomorphology, 218 (2014), 52-62.

    Tomczyk A. M., Ewertowski M., 2010: Changes of Arctic landscape due to human impact, north part of Billefjorden area, Svalbard. Quaestiones Geographicae, 29(A/1), 75-83.

    Van der Meij W. M., Temme A. J. A. M., de Kleijn C. M. F. J. J. , Reimann T., Heuvelink G. B. M., Zwoliński Z., Rachlewicz G., Rymer K. i Sommer M., 2016: Arctic soil development on a series of marine terraces on Central Spitsbergen, Svalbard: a combined geochronology, fieldwork and modelling approach. SOIL, 2, 221-240. DOI: 10.5194/soil-2-221-2016.

    Wojciechowski A., 1989: Sedimentation in small proglacial lakes in the H?rbyebreen marginal zone, central Spitsbergen. Polish Polar Research, 10(3), 385-399.

    Zwoliński Z., Rachlewicz G., Mazurek M. i Paluszkiewicz R., 2007: The geoecological model for small tundra lakes, Ebbadalen, Central Spitsbergen. Landform Analysis, vol. 5, 113-118.

    Zwoliński Z., Mazurek M., Paluszkiewicz R. i Rachlewicz G., 2008: The matter fluxes in the geoecosystem of small tundra lakes, Petuniabukta coast, Billefjorden, Central Spitsbergen. Zeitschr. Geomorph, 52, Suppl. 1, 79-101.

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