Your search keyword '"Klippel L"' showing total 4 results

1. Hourly resolved climate response of picea abies beyond its natural distribution range

Author

Klippel, L., Claudia Hartl, Lindén, J., Kochbeck, M., Emde, K., and Esper, J.

2. Prominent role of volcanism in Common Era climate variability and human history

Author

Büntgen, U, Arseneault, D, Boucher, É, Churakova (Sidorova), OV, Gennaretti, F, Crivellaro, A, Hughes, MK, Kirdyanov, AV, Klippel, L, Krusic, PJ, Linderholm, HW, Ljungqvist, FC, Ludescher, J, McCormick, M, Myglan, VS, Nicolussi, K, Piermattei, A, Oppenheimer, C, Reinig, F, Sigl, M, Vaganov, EA, and Esper, J

Subjects

Human history, 13. Climate action, Dendroclimatology, Climate reconstruction, Tree-ring width, Volcanic eruptions, Northern Hemisphere

Abstract

© 2020 Elsevier GmbH Climate reconstructions for the Common Era are compromised by the paucity of annually-resolved and absolutely-dated proxy records prior to medieval times. Where reconstructions are based on combinations of different climate archive types (of varying spatiotemporal resolution, dating uncertainty, record length and predictive skill), it is challenging to estimate past amplitude ranges, disentangle the relative roles of natural and anthropogenic forcing, or probe deeper interrelationships between climate variability and human history. Here, we compile and analyse updated versions of all the existing summer temperature sensitive tree-ring width chronologies from the Northern Hemisphere that span the entire Common Era. We apply a novel ensemble approach to reconstruct extra-tropical summer temperatures from 1 to 2010 CE, and calculate uncertainties at continental to hemispheric scales. Peak warming in the 280s, 990s and 1020s, when volcanic forcing was low, was comparable to modern conditions until 2010 CE. The lowest June–August temperature anomaly in 536 not only marks the beginning of the coldest decade, but also defines the onset of the Late Antique Little Ice Age (LALIA). While prolonged warmth during Roman and medieval times roughly coincides with the tendency towards societal prosperity across much of the North Atlantic/European sector and East Asia, major episodes of volcanically-forced summer cooling often presaged widespread famines, plague outbreaks and political upheavals. Our study reveals a larger amplitude of spatially synchronized summer temperature variation during the first millennium of the Common Era than previously recognised.

3. Jet stream controls on European climate and agriculture since 1300 CE.

Author

Xu G, Broadman E, Dorado-Liñán I, Klippel L, Meko M, Büntgen U, De Mil T, Esper J, Gunnarson B, Hartl C, Krusic PJ, Linderholm HW, Ljungqvist FC, Ludlow F, Panayotov M, Seim A, Wilson R, Zamora-Reyes D, and Trouet V

Subjects

Humans, Climate Change statistics & numerical data, Droughts history, Droughts statistics & numerical data, Edible Grain economics, Edible Grain history, Edible Grain supply & distribution, Epidemics history, Epidemics statistics & numerical data, Europe, History, 15th Century, History, 16th Century, History, 17th Century, History, 18th Century, History, 19th Century, History, 20th Century, History, 21st Century, History, Medieval, Mortality history, Rain, Seasons, Temperature, Trees growth & development, Vitis, Wildfires history, Wildfires statistics & numerical data, Atmospheric Pressure, Altitude, Climate, Crop Production history, Crop Production statistics & numerical data, Wind

Abstract

The jet stream is an important dynamic driver of climate variability in the Northern Hemisphere mid-latitudes 1-3 . Modern variability in the position of summer jet stream latitude in the North Atlantic-European sector (EU JSL) promotes dipole patterns in air pressure, temperature, precipitation and drought between northwestern and southeastern Europe. EU JSL variability and its impacts on regional climatic extremes and societal events are poorly understood, particularly before anthropogenic warming. Based on three temperature-sensitive European tree-ring records, we develop a reconstruction of interannual summer EU JSL variability over the period 1300-2004 CE (R 2  = 38.5%) and compare it to independent historical documented climatic and societal records, such as grape harvest, grain prices, plagues and human mortality. Here we show contrasting summer climate extremes associated with EU JSL variability back to 1300 CE as well as biophysical, economic and human demographic impacts, including wildfires and epidemics. In light of projections for altered jet stream behaviour and intensified climate extremes, our findings underscore the importance of considering EU JSL variability when evaluating amplified future climate risk., (© 2024. The Author(s).)

Published

2024

4. Revising Alpine summer temperatures since 881 CE.

Author

Kuhl E, Esper J, Schneider L, Trouet V, Kunz M, Klippel L, Büntgen U, and Hartl C

Abstract

Europe experienced severe heat waves during the last decade, which impacted ecological and societal systems and are likely to increase under projected global warming. A better understanding of pre-industrial warm-season changes is needed to contextualize these recent trends and extremes. Here, we introduce a network of 352 living and relict larch trees ( Larix decidua Mill. ) from the Matter and Simplon valleys in the Swiss Alps to develop a maximum latewood density (MXD) chronology calibrating at r = 0.8 (p > 0.05, 1901-2017 CE) against May-August temperatures over Western Europe. Machine learning is applied to identify historical wood samples aligning with growth characteristics of sites from elevations above 1900 m asl to extend the modern part of the chronology back to 881 CE. The new Alpine record reveals warmer conditions in the tenth century, followed by an extended cold period during the late Medieval times, a less-pronounced Little Ice Age culminating in the 1810s, and prolonged anthropogenic warming until present. The Samalas eruption likely triggered the coldest reconstructed summer in Western Europe in 1258 CE (-2.32 °C), which is in line with a recently published MXD-based reconstruction from the Spanish Pyrenees. Whereas the new Alpine reconstruction is potentially constrained in the lowest frequency, centennial timescale domain, it overcomes variance biases in existing state-of-the-art reconstructions and sets a new standard in site-control of historical samples and calibration/ verification statistics., Supplementary Information: The online version contains supplementary material available at 10.1007/s00382-024-07195-1., Competing Interests: Competing interestsThe authors declare that they have no relevant financial or non-financial conflict of interest., (© The Author(s) 2024.)

Published

2024