Publications - Physical Geography - Department of Earth Sciences

Neogene global climate change and East Asian dust sources: Combined rutile geochemistry and zircon U Pb analysis from the northern Chinese Loess Plateau.
Bohm, K., Kaakinen, A., Stevens, T., Lahaye, Y., O'Brien, H. et al. (2023). Global and Planetary Change, . vol. 221 DOI
Impact of snow distribution modelling for runoff predictions.
Clemenzi, I., Gustafsson, D., Marchand, W., Norell, B., Zhang, J. et al. (2023). Nordic Hydrology, . vol. 54, ss. 633-647 DOI
Revised historical Northern Hemisphere black carbon emissions based on inverse modeling of ice core records.
Eckhardt, S., Pisso, I., Evangeliou, N., Groot Zwaaftink, C., Plach, A. et al. (2023). Nature Communications, . vol. 14 DOI
Reconciling ice dynamics and bed topography with a versatile and fast ice thickness inversion.
Frank, T., van Pelt, W., Kohler, J. (2023). The Cryosphere, vol. 17, ss. 4021-4045 DOI
The Subglacial Lake That Wasn't There: Improved Interpretation From Seismic Data Reveals a Sediment Bedform at Isunnguata Sermia.
Hofstede, C., Wilhelms, F., Neckel, N., Fritzsche, D., Beyer, S. et al. (2023). Journal of Geophysical Research - Earth Surface, . vol. 128 DOI
Status of Earth Observation and Remote Sensing Applications in Svalbard.
Jawak, S., Pohjola, V., Kääb, A., Andersen, B., Blaszczyk, M. et al. (2023). Remote Sensing, . vol. 15 DOI
Selection processes of Arctic seasonal glacier snowpack bacterial communities.
Keuschnig, C., Vogel, T., Barbaro, E., Spolaor, A., Koziol, K. et al. (2023). Microbiome, . vol. 11 DOI
Greenland and Canadian Arctic ice temperature profiles database.
Løkkegaard, A., Mankoff, K., Zdanowicz, C., Clow, G., Lüthi, M. et al. (2023). The Cryosphere, . vol. 17, ss. 3829-3845 DOI
High-resolution OSL dating of loess in Adventdalen, Svalbard: Late Holocene dust activity and permafrost development.
Rasmussen, C., Christiansen, H., Buylaert, J., Cunningham, A., Schneider, R. et al. (2023). Quaternary Science Reviews, vol. 310 DOI
Defining paleoclimatic routes and opportunities for hominin dispersals across Iran.
Shoaee, M., Breeze, P., Drake, N., Hashemi, S., Vahdati Nasab, H. et al. (2023). PLOS ONE, . vol. 18 DOI
Geographic object‐based image analysis (GEOBIA) of the distribution and characteristics of aeolian sand dunes in Arctic Sweden.
Stammler, M., Stevens, T., Hölbling, D. (2023). Permafrost and Periglacial Processes, . vol. 34, ss. 22-36 DOI
Spatial variability in winter mass balance on Storglaciären modelled with a terrain-based approach.
Terleth, Y., van Pelt, W., Pettersson, R. (2023). Journal of Glaciology, . vol. 69, ss. 749-761 DOI
Eurasian Ice Sheet derived meltwater pulses and their role in driving atmospheric dust activity: Late Quaternary loess sources in SE England.
Baykal, Y., Stevens, T., Bateman, M., Pfaff, K., Sechi, D. et al. (2022). Quaternary Science Reviews, vol. 296, ss. 107804-107804 DOI
The provenance of late Cenozoic East Asian Red Clay: Tectonic-metamorphic history of potential source regions and a novel combined zircon-rutile approach.
Bohm, K., Stevens, T., Kaakinen, A., Lahaye, Y., O'Brien, H. et al. (2022). Earth-Science Reviews, . vol. 225 DOI
Searching for potential multi-hazard events during the last 1.5 million years of the Pleistocene epoch.
Bradak, B., Gomez, C., Kereszturi, Á., Stevens, T. (2022). Forum Geografi, . vol. 36, ss. 39-53 DOI
Potential drivers of disparity in early Middle Pleistocene interglacial climate response over Eurasia.
Bradák, B., Újvári, G., Stevens, T., Bógalo, M., González, M. et al. (2022). Palaeogeography, Palaeoclimatology, Palaeoecology, . vol. 585 DOI
Loess in Britain and Ireland: Formation, modification and environmental significance, a review in memory of John Catt (1937–2017).
Bunce, C., Smalley, I., Stevens, T., Assadi-Langroudi, A. (2022). Proceedings of the Geologists' Association DOI
Sources of riverine mercury across the Mackenzie River Basin: inferences from a combined Hg C isotopes and optical properties approach.
Campeau, A., Eklöf, K., Soerensen, A., Åkerblom, S., Yuan, S. et al. (2022). Science of the Total Environment, . vol. 806 DOI
Revisiting Late Pleistocene Loess–Paleosol Sequences in the Azov Sea Region of Russia: Chronostratigraphy and Paleoenvironmental Record.
Chen, J., Stevens, T., Yang, T., Qiang, M., Gennady, M. et al. (2022). Frontiers in Earth Science, . vol. 9 DOI
Arctic mercury cycling.
Dastoor, A., Angot, H., Bieser, J., Christensen, J., Douglas, T. et al. (2022). Nature Reviews Earth & Environment, . vol. 3, ss. 270-286 DOI
The provenance of Danubian loess.
Fenn, K., Millar, I., Durcan, J., Thomas, D., Banak, A. et al. (2022). Earth-Science Reviews, . vol. 226, ss. 103920- DOI
Historical glacier change on Svalbard predicts doubling of mass loss by 2100.
Geyman, E., Van Pelt, W., Maloof, A., Faste Aas, H., Kohler, J. (2022). Nature, . vol. 601, ss. 374-379 DOI
Dominant precessional forcing of the East Asian summer monsoon since 260 ka.
Guo, B., Nie, J., Stevens, T., Buylaert, J., Peng, T. et al. (2022). Geology, . vol. 50, ss. 1372-1376 DOI
Radar attenuation demonstrates advective cooling in the Siple Coast ice streams.
Hills, B., Christianson, K., Jacobel, R., Conway, H., Pettersson, R. (2022). Journal of Glaciology, . vol. 69, ss. 566-576 DOI
Seasonal glacier and snow loading in Svalbard recovered from geodetic observations.
Kierulf, H., Van Pelt, W., Petrov, L., Dähnn, M., Kirkvik, A. et al. (2022). Geophysical Journal International, . vol. 229, ss. 408-425 DOI
Long-term firn and mass balance modelling for Abramov Glacier in the data-scarce Pamir Alay.
Kronenberg, M., van Pelt, W., Machguth, H., Fiddes, J., Hoelzle, M. et al. (2022). The Cryosphere, . vol. 16, ss. 5001-5022 DOI
LoessFest 2018, Volgograd, Russia.
Kurbanov, R., Lu, H., Stevens, T., Markovic, S. (2022). Quaternary International, . vol. 620, ss. 1-3 DOI
A detailed luminescence chronology of the Lower Volga loess-palaeosol sequence at Leninsk.
Kurbanov, R., Buylaert, J., Stevens, T., Taratunina, N., Belyaev, V. et al. (2022). Quaternary Geochronology, . vol. 73 DOI
Quaternary sediment sources and loess transport pathways in the Black Sea - Caspian Sea region identified by detrital zircon U-Pb geochronology.
Költringer, C., Stevens, T., Lindner, M., Baykal, Y., Ghafarpour, A. et al. (2022). Global and Planetary Change, . vol. 209 DOI
Chinese loess and the Asian monsoon: What we know and what remains unknown.
Lu, H., Wang, X., Wang, Y., Zhang, X., Yi, S. et al. (2022). Quaternary International, . vol. 620, ss. 85-97 DOI
Direct photogrammetry with multispectral imagery for UAV-based snow depth estimation.
Maier, K., Nascetti, A., Van Pelt, W., Rosqvist, G. (2022). ISPRS journal of photogrammetry and remote sensing (Print), . vol. 186, ss. 1-18 DOI
Decoupled Chinese Loess Plateau dust deposition and Asian aridification at millennial and tens of millennial timescales.
Peng, F., Nie, J., Stevens, T., Pan, B. (2022). Geophysical Research Letters, . vol. 49 DOI
Detailed luminescence dating of dust mass accumulation rates over the last two glacial-interglacial cycles from the Irig loess-palaeosol sequence, Carpathian Basin.
Peric, Z., Stevens, T., Obreht, I., Hambach, U., Lehmkuhl, F. et al. (2022). Global and Planetary Change, . vol. 215 DOI
Dataset of dust mass accumulation rates for the loess-palaeosol sequences from the Carpathian Basin.
Perić, Z., Stevens, T., Obreht, I., Marković, S. (2022). Data in Brief, . vol. 44 DOI
Age, formation and significance of loess deposits in central Sweden.
Stevens, T., Sechi, D., Tziavaras, C., Schneider, R., Banak, A. et al. (2022). Earth Surface Processes and Landforms, . vol. 47, ss. 3276-3301 DOI
Comparison of High-Resolution 14C and Luminescence-Based Chronologies of the MIS 2 Madaras Loess/Paleosol Sequence, Hungary: Implications for Chronological Studies.
Sümegi, P., Molnár, D., Gulyás, S., Stevens, T., Makó, L. et al. (2022). Quaternary, . vol. 5 DOI
First high-resolution luminescence dating of loess in Western Siberia.
Volvakh, N., Kurbanov, R., Zykina, V., Murray, A., Stevens, T. et al. (2022). Quaternary Geochronology, . vol. 73 DOI
Resolving conflicting models of late Miocene East Asian summer monsoon intensity recorded in Red Clay deposits on the Chinese Loess Plateau.
Wang, X., Nie, J., Stevens, T., Zhang, H., Xiao, W. (2022). Earth-Science Reviews, . vol. 234, ss. 104200-104200 DOI
Large-number detrital zircon U-Pb ages reveal global cooling caused the formation of the Chinese Loess Plateau during Late Miocene.
Zhang, H., Lu, H., He, J., Xie, W., Wang, H. et al. (2022). Science Advances, . vol. 8 DOI
Spatial and temporal variations in riverine mercury in the Mackenzie River Basin, Canada, from community-based water quality monitoring data.
Åkerblom, S., Zdanowicz, C., Campeau, A., Soerensen, A., Hewitt, J. (2022). Science of the Total Environment, . vol. 853 DOI