Abstract
Abstract. Temperature reconstructions from the Northern Hemisphere (NH) generally indicate cooling over the Holocene, which is often attributed to decreasing summer insolation. However, climate model simulations predict that rising atmospheric CO2 concentrations and the collapse of the Laurentide Ice Sheet caused mean annual warming during this epoch. This contrast could reflect a seasonal bias in temperature proxies, and particularly a lack of proxies that record cold (late fall–early spring) season temperatures, or inaccuracies in climate model predictions of NH temperature. We reconstructed winter–spring temperatures during the Common Era (i.e., the last 2000 years) using alkenones, lipids produced by Isochrysidales haptophyte algae that bloom during spring ice-out, preserved in sediments from Vestra Gíslholtsvatn (VGHV), southwest Iceland. Our record indicates that winter–spring temperatures warmed during the last 2000 years, in contrast to most NH averages. Sensitivity tests with a lake energy balance model suggest that warmer winter and spring air temperatures result in earlier ice-out dates and warmer spring lake water temperatures and therefore warming in our proxy record. Regional air temperatures are strongly influenced by sea surface temperatures during the winter and spring season. Sea surface temperatures (SSTs) respond to both changes in ocean circulation and gradual changes in insolation. We also found distinct seasonal differences in centennial-scale, cold-season temperature variations in VGHV compared to existing records of summer and annual temperatures from Iceland. Multi-decadal to centennial-scale changes in winter–spring temperatures were strongly modulated by internal climate variability and changes in regional ocean circulation, which can result in winter and spring warming in Iceland even after a major negative radiative perturbation.
Highlights
Temperatures in the Northern Hemisphere (NH) are generally thought to have cooled over the past 2000 years, culminating in the Little Ice Age (LIA, ca. 1450–1850 CE) (Kaufman et al, 2009; PAGES 2K Consortium, 2013, 2019; McKay and Kaufman, 2014)
Species mixing affects the U3K7 temperature record, but regardless of the correction applied to the data, there is an increase in the mean U3K7 values from 0–1000 to 1001–2000 CE
Our record lacks a local calibration, we argue that the U3K7 record from VGHV provides a robust, albeit qualitative, record of winter–spring temperatures given the unique seasonal growth ecology of Group I haptophytes in NH lakes
Summary
Temperatures in the Northern Hemisphere (NH) are generally thought to have cooled over the past 2000 years, culminating in the Little Ice Age (LIA, ca. 1450–1850 CE) (Kaufman et al, 2009; PAGES 2K Consortium, 2013, 2019; McKay and Kaufman, 2014). The majority of NH temperature reconstructions are based on proxies that respond to climate change during the warm season and may not capture trends in annual or winter and spring temperatures (Liu et al, 2014; PAGES 2K Consortium, 2019) This limits our understanding of major atmospheric phenomena in the NH, such as the North Atlantic Oscillation (NAO), which dominates wintertime variability, as well as changes in ocean circulation and other phenomena driving variability in the extent of Arctic sea ice. Many oceanic and atmospheric processes that influence surface climate in the Atlantic and the broader NH are centered in the high North Atlantic region, making it an important location to study changes during the winter and spring seasons (Hurrell, 1995; Yeager and Robson, 2017). The high sedimentation rates in Icelandic lakes, along with well-known volcanic eruptions
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