Abstract
We investigate the effects of solar forcing on the North Atlantic (NA) summer climate, in climate simulations with Earth System Models (ESMs), over the preindustrial past millennium (AD 850–1849). We use one simulation and a four-member ensemble performed with the MPI-ESM-P and CESM-LME models, respectively, forced only by low-scaling variations in Total Solar Irradiance (TSI). We apply linear methods (correlation and regression) and composite analysis to estimate the NA surface and tropospheric climatic responses to decadal solar variability. Linear methods in the CESM ensemble indicate a weak summer response in sea-level pressure (SLP) and 500-hPa geopotential height to TSI, with decreased values over Greenland and increased values over the NA subtropics. Composite analysis indicates that, during high-TSI periods, SLP decreases over eastern Canada and the geopotential height at 500-hPa increases over the subtropical NA. The possible summer response of SSTs is overlapped by model internal variability. Therefore, for low-scaling TSI changes, state-of-the-art ESMs disagree on the NA surface climatic effect of solar forcing indicated by proxy-based studies during the preindustrial millennium. The analysis of control simulations indicates that, in all climatic variables studied, spurious patterns of apparent solar response may arise from the analysis of single model simulations.
Highlights
IntroductionPublisher’s Note: MDPI stays neutral with regard to jurisdictional claims in published maps and institutional affiliations
Using the methodologies described before, we investigate the surface and tropospheric response to solar forcing over the North Atlantic during summer
We investigated the response of the summer North Atlantic (NA) modeled climate to solar forcing in the preindustrial last millennium
Summary
Publisher’s Note: MDPI stays neutral with regard to jurisdictional claims in published maps and institutional affiliations. Changes in the climate system may be a result of internal climate variability or external influences that may be either anthropogenic or natural (i.e., orbital, solar, or volcanic forcing). The human influence on global temperature since the start of the industrial era (after AD 1850) has very likely exceeded the impact of natural forcings [1]. During the pre-industrial era, externally driven climate change at decadal-to-multidecadal time scales is considered to be forced primarily by variation in solar output and by volcanic eruptions [2,3,4]. In contrast to volcanic forcing, solar forcing may cause long-term (decadal mean) continental and regional climate changes that are greater than unforced (internal) variability [5]
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