Publications
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Neogene global climate change and East Asian dust sources: Combined rutile geochemistry and zircon U Pb analysis from the northern Chinese Loess Plateau.
(2023). Global and Planetary Change, ss. 104049-104049 DOI -
Revised historical Northern Hemisphere black carbon emissions based on inverse modeling of ice core records.
(2023). Nature Communications, . vol. 14 DOI -
Eurasian Ice Sheet derived meltwater pulses and their role in driving atmospheric dust activity: Late Quaternary loess sources in SE England.
(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.
(2022). Earth-Science Reviews, . vol. 225 DOI -
Searching for potential multi-hazard events during the last 1.5 million years of the Pleistocene epoch.
(2022). Forum Geografi, . vol. 36, ss. 39-53 DOI -
Potential drivers of disparity in early Middle Pleistocene interglacial climate response over Eurasia.
(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).
(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.
(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.
(2022). Frontiers in Earth Sciences, . vol. 9 DOI -
Arctic mercury cycling.
(2022). Nature Reviews Earth & Environment, . vol. 3, ss. 270-286 DOI -
The provenance of Danubian loess.
(2022). Earth-Science Reviews, . vol. 226, ss. 103920- DOI -
Historical glacier change on Svalbard predicts doubling of mass loss by 2100.
(2022). Nature, . vol. 601, ss. 374-379 DOI -
Dominant precessional forcing of the East Asian summer monsoon since 260 ka.
(2022). Geology DOI -
Seasonal glacier and snow loading in Svalbard recovered from geodetic observations.
(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.
(2022). The Cryosphere, . vol. 16, ss. 5001-5022 DOI -
LoessFest 2018, Volgograd, Russia.
(2022). Quaternary International, . vol. 620, ss. 1-3 DOI -
A detailed luminescence chronology of the Lower Volga loess-palaeosol sequence at Leninsk.
(2022). Quaternary Geochronology, . ss. 101376-101376 DOI -
Quaternary sediment sources and loess transport pathways in the Black Sea - Caspian Sea region identified by detrital zircon U-Pb geochronology.
(2022). Global and Planetary Change, . vol. 209 DOI -
Chinese loess and the Asian monsoon: What we know and what remains unknown.
(2022). Quaternary International, . vol. 620, ss. 85-97 DOI -
Direct photogrammetry with multispectral imagery for UAV-based snow depth estimation.
(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.
(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.
(2022). Global and Planetary Change, . vol. 215 DOI -
Dataset of dust mass accumulation rates for the loess-palaeosol sequences from the Carpathian Basin.
(2022). Data in Brief, . ss. 108555-108555 DOI -
Geographic object‐based image analysis (GEOBIA) of the distribution and characteristics of aeolian sand dunes in Arctic Sweden.
(2022). Permafrost and Periglacial Processes DOI -
Age, formation and significance of loess deposits in central Sweden.
(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.
(2022). Quaternary, . vol. 5 DOI -
First high-resolution luminescence dating of loess in Western Siberia.
(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.
(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.
(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.
(2022). Science of the Total Environment, . vol. 853 DOI -
Greenland ice core record of last glacial dust sources and atmospheric circulation.
(2022). Journal of Geophysical Research - Atmospheres . DOI -
Measurement report: Spatial variations in ionic chemistry and water-stable isotopes in the snowpack on glaciers across Svalbard during the 2015-2016 snow accumulation season.
(2021). Atmospheric Chemistry And Physics, vol. 21, ss. 3163-3180 DOI -
Detrital zircon U–Pb age analysis of last glacial loess sources and proglacial sediment dynamics in the Northern European Plain.
(2021). Quaternary Science Reviews, vol. 274 DOI -
Feeding at the front line: interannual variation in the use of glacier fronts by foraging black-legged kittiwakes.
(2021). Marine Ecology Progress Series, vol. 677, ss. 197-208 DOI -
Magnetic susceptibility in the European Loess Belt: New and existing models of magnetic enhancement in loess.
(2021). Palaeogeography, Palaeoclimatology, Palaeoecology, vol. 569 DOI -
Results from the Ice Thickness Models Intercomparison eXperiment Phase 2 (ITMIX2).
(2021). Frontiers in Earth Science, vol. 8 DOI -
Late Pleistocene Climate and Dust Source From the Mobarakabad Loess–Paleosol Sequence, Northern Foothills of the Alborz Mountains, Northern Iran.
(2021). Frontiers in Earth Science, vol. 9 DOI -
SIOS's Earth Observation (EO), Remote Sensing (RS), and Operational Activities in Response to COVID-19.
(2021). Remote Sensing, . vol. 13 DOI -
Svalbard snow and sea-ice cover: comparing satellite data, on-site measurements, and modelling results (SvalSCESIA).
(2021). I Moreno-Ibáñez M., Hagen J.O., Hübner C., Lihavainen H. & Zaborska A (red.) SESS report 2020, Longyearbyen: Svalbard Integrated Arctic Earth Observing System. ss. 220-235 DOI -
Palaeoenvironmental implications from Lower Volga loess - Joint magnetic fabric and multi-proxy analyses.
(2021). Quaternary Science Reviews, . vol. 267, ss. 107057- DOI -
Enviromagnetic study of Late Quaternary environmental evolution in Lower Volga loess sequences, Russia.
(2021). Quaternary Research, vol. 103, ss. 49-73 DOI -
Distinct periods of fan aggradation and incision for tributary valleys of different sizes along the Bailong River, eastern margin of the Tibetan Plateau.
(2021). Geomorphology, . vol. 373 DOI -
Satellite and modelling based snow season time series for Svalbard: Inter-comparisons and assessment of accuracy (SATMODSNOW).
(2021). I Moreno-Ibáñez et al. (red.) SESS Report 2020 – The State of Environmental Science in Svalbard, Longyearbyen: Svalbard Integrated Arctic Earth Observing System. ss. 202-219 DOI -
Water content of firn at Lomonosovfonna, Svalbard, derived from subsurface temperature measurements.
(2021). Journal of Glaciology, vol. 67, ss. 921-932 DOI -
Geomorphological evolution of the Petrovaradin Fortress Palaeolithic site (Novi Sad, Serbia).
(2021). Quaternary Research, vol. 103, ss. 21-34 DOI -
Firn changes at Colle Gnifetti revealed with a high-resolution process-based physical model approach.
(2021). The Cryosphere, vol. 15, ss. 3181-3205 DOI -
Late Quaternary Dust, Loess and Desert Dynamics in Upwind Areas of the Chinese Loess Plateau.
(2021). Frontiers in Earth Sciences, vol. 9 DOI -
Detrital zircon U-Pb ages and source of the late Palaeocene Thanet Formation, Kent, SE England.
(2021). Proceedings of the Geologists' Association, vol. 132, ss. 240-248 DOI -
Complementary approaches towards a universal model of glacier surges.
(2021). Frontiers in Earth Science, vol. 9 DOI -
Accelerating future mass loss of Svalbard glaciers from a multi-model ensemble.
(2021). Journal of Glaciology, vol. 67, ss. 485-499 DOI -
A compilation of snow cover datasets for Svalbard: A multi-sensor, multi-model study.
(2021). Remote Sensing, vol. 13 DOI -
Climatic Forcing of Plio-Pleistocene Formation of the Modern Limpopo River, South Africa.
(2021). Geophysical Research Letters, vol. 48 DOI -
Elemental and water-insoluble organic carbon in Svalbard snow: a synthesis of observations during 2007–2018.
(2021). Atmospheric Chemistry And Physics, vol. 21, ss. 3035-3057 DOI -
Improving the snowpack monitoring in the mountainous areas of Sweden from space: a machine learning approach.
(2021). Environmental Research Letters, vol. 16 DOI -
Geomagnetic dipole moment variations for the last glacial period inferred from cosmogenic radionuclides in Greenland ice cores via disentangling the climate and production signals.
(2021). Quaternary Science Reviews, . vol. 258 DOI -
Stadial-interstadial temperature variations in East Central Europe preceding the Last Glacial Maximum.
(2021). Paleoceanography and Paleoclimatology, . vol. 36 DOI -
A constant Chinese Loess Plateau dust source since the late Miocene.
(2020). Quaternary Science Reviews, vol. 227 DOI -
Controls on the C-14 Content of Dissolved and Particulate Organic Carbon Mobilized Across the Mackenzie River Basin, Canada.
(2020). Global Biogeochemical Cycles, . vol. 34 DOI -
Magnetic susceptibility parameters as proxies for desert sediment provenance.
(2020). Aeolian Research, vol. 46 DOI -
Beach ridges of Dali Lake in Inner Mongolia reveal precipitation variation during the Holocene.
(2020). Journal of Quaternary Science, vol. 35, ss. 716-725 DOI -
Formation and evolution of an extensive blue ice moraine in central Transantarctic Mountains, Antarctica.
(2020). Journal of Glaciology, . vol. 66, ss. 49-60 DOI -
Differential ice volume and orbital modulation of Quaternary moisture patterns between Central and East Asia.
(2020). Earth and Planetary Science Letters, . vol. 530 DOI -
Low elevation of Svalbard glaciers drives high mass loss variability.
(2020). Nature Communications, . vol. 11 DOI -
A sinistral Helicopsis cf. instabilis (Rossmässler, 1838) from Romanian loess.
(2020). Folia Malacologica, vol. 28, ss. 91-93 DOI -
The missing pieces for better future predictions in subarctic ecosystems: A Torneträsk case study.
(2020). Ambio, . vol. 50, ss. 375-392 DOI -
Revised estimates of recent mass loss rates for Penny Ice Cap, Baffin Island, based on 2005-2014 elevation changes modified for firn densification.
(2020). Journal of Geophysical Research - Earth Surface, . vol. 125 DOI -
New data, new techniques and new challenges for updating the state of Svalbard glaciers (SvalGlac).
(2020). I Van den Heuvel et al. (red.) SESS report 2019, Longyearbyen: Svalbard Integrated Arctic Earth Observing System. ss. 109-134 -
Reconciling Svalbard Glacier Mass Balance.
(2020). Frontiers in Earth Science, vol. 8 DOI -
Age and significance of late Pleistocene Lithophyllum byssoides intertidal algal ridge, NW Sardinia, Italy.
(2020). Sedimentary Geology, vol. 400 DOI -
Abrupt last glacial dust fall over southeast England associated with dynamics of the British-Irish ice sheet.
(2020). Quaternary Science Reviews, . vol. 250 DOI -
The firn meltwater Retention Model Intercomparison Project (RetMIP): evaluation of nine firn models at four weather station sites on the Greenland ice sheet.
(2020). The Cryosphere, . vol. 14, ss. 3785-3810 DOI -
Evidence for elevation-dependent warming in the St. Elias Mountains, Yukon, Canada.
(2020). Journal of Climate, . vol. 33, ss. 3253-3269 DOI -
Insight into the Hg sources by stable isotopes of mercury in the largest Arctic river in North America.
(2020). I -
Closing the mass budget of a tidewater glacier: the example of Kronebreen, Svalbard.
(2019). Journal of Glaciology, vol. 65, ss. 136-148 DOI -
GlacierMIP - A model intercomparison of global-scale glacier mass-balance models and projections.
(2019). Journal of Glaciology, . vol. 65, ss. 453-467 DOI -
Calving controlled by melt-under-cutting: detailed calving styles revealed through time-lapse observations.
(2019). Annals of Glaciology, . vol. 60, ss. 20-31 DOI -
Characterization of seasonal glacial seismicity from a single-station on-ice record at Holtedahlfonna, Svalbard.
(2019). Annals of Glaciology, vol. 60, ss. 23-36 DOI -
Thermal conductivity of firn at Lomonosovfonna, Svalbard, derived from subsurface temperature measurements.
(2019). The Cryosphere, vol. 13, ss. 1843-1859 DOI -
Scientific workflows applied to the coupling of a continuum (Elmer v8.3) and a discrete element (HiDEM v1.0) ice dynamic model.
(2019). Geoscientific Model Development, . vol. 12, ss. 3001-3015 DOI -
Quartz OSL dating of late quaternary Chinese and Serbian loess: A cross Eurasian comparison of dust mass accumulation rates.
(2019). Quaternary International, vol. 502, ss. 30-44 DOI -
Comparison of snow accumulation events on two High Arctic glaciers to model-derived and observed precipitation.
(2019). Polar Research, vol. 38 DOI -
Applications in loessic environments.
(2019). I Mark D Bateman (red.) Handbook of luminescence dating, Dunbeath, Scotland: Whittles Publishing. ss. 153-190 -
Automatic detection of calving events from time-lapse imagery at Tunabreen, Svalbard.
(2019). Geoscientific Instrumentation, Methods and Data Systems, vol. 8, ss. 113-127 DOI -
A long-term dataset of climatic mass balance, snow conditions, and runoff in Svalbard (1957–2018).
(2019). The Cryosphere, vol. 13, ss. 2259-2280 DOI -
Testing contrasting models of the formation of the upper Yellow River usingheavy-mineral data from the Yinchuan Basin drill cores.
(2019). Geophysical Research Letters, . vol. 46, ss. 10338-10345 DOI -
Strategies and Best Practices for Monitoring Seasonal Snow Cover Composition.
(2019). I . -
Identifying terrestrial sources of mercury in streams of the Mackenzie River Basin, NW Canada.
(2019). I -
Mercury inputs to the Mackenzie River and the Beaufort Sea:: Future impacts of permafrost thaw.
(2019). I -
Insights into the provenance of the Chinese Loess Plateau from joint zircon U-Pb and garnet geochemical analysis of last glacial loess.
(2018). Quaternary Research, vol. 89, ss. 645-659 DOI -
The Ice-Free Topography of Svalbard.
(2018). Geophysical Research Letters, vol. 45, ss. 11760-11769 DOI -
On the Holocene evolution of the Ayeyawady megadelta.
(2018). Earth Surface Dynamics, vol. 6, ss. 451-466 DOI -
Global-scale hydrological response to future glacier mass loss.
(2018). Nature Climate Change, . vol. 8, ss. 135-140 DOI -
Decadal topographic change in the McMurdo Dry Valleys of Antarctica: Thermokarst subsidence, glacier thinning, and transfer of water storage from the cryosphere to the hydrosphere.
(2018). Geomorphology, vol. 323, ss. 80-97 DOI -
Orbital scale lake evolution in the Ejina Basin, central Gobi Desert, China revealed by K-feldspar luminescence dating of paleolake shoreline features.
(2018). Quaternary International, vol. 482, ss. 109-121 DOI -
Alluvial fan aggradation/incision history of the eastern Tibetan plateau margin and implications for debris flow/debris-charged flood hazard.
(2018). Geomorphology, vol. 318, ss. 203-216 DOI -
Subglacial topography, ice thickness, and bathymetry of Kongsfjorden, northwestern Svalbard.
(2018). Earth System Science Data, . vol. 10, ss. 1769-1781 DOI -
Loess correlations – Between myth and reality.
(2018). Palaeogeography, Palaeoclimatology, Palaeoecology, vol. 509, ss. 4-23 DOI -
The Crvenka loess-paleosol sequence: A record of continuous grassland domination in the southern Carpathian Basin during the Late Pleistocene.
(2018). Palaeogeography, Palaeoclimatology, Palaeoecology, vol. 509, ss. 33-46 DOI -
Rapid incision of the Mekong River in the middle Miocene linked to monsoonal precipitation.
(2018). Nature Geoscience, vol. 11, ss. 944-948 DOI -
An 800-year high-resolution black carbon ice core record from Lomonosovfonna, Svalbard.
(2018). Atmospheric Chemistry And Physics, . vol. 18, ss. 12777-12795 DOI