Changes in extratropical storm track cloudiness 1983–2008: observational support for a poleward shift

Projections of future climate depend critically on refined estimates of climate sensitivity. Recent progress in temperature proxies dramatically increases the magnitude of warming reconstructed from early Paleogene greenhouse climates and demands a close examination of the forcing and feedback mechanisms that maintained this warmth and the broad dynamic range that these paleoclimate records attest to. Here, we show that several complementary resolutions to these questions are possible in the context of model simulations using modern and early Paleogene configurations. We find that (i) changes in boundary conditions representative of slow "Earth system" feedbacks play an important role in maintaining elevated early Paleogene temperatures, (ii) radiative forcing by carbon dioxide deviates significantly from pure logarithmic behavior at concentrations relevant for simulation of the early Paleogene, and (iii) fast or "Charney" climate sensitivity in this model increases sharply as the climate warms. Thus, increased forcing and increased slow and fast sensitivity can all play a substantial role in maintaining early Paleogene warmth. This poses an equifinality problem: The same climate can be maintained by a different mix of these ingredients; however, at present, the mix cannot be constrained directly from climate proxy data. The implications of strongly state-dependent fast sensitivity reach far beyond the early Paleogene. The study of past warm climates may not narrow uncertainty in future climate projections in coming centuries because fast climate sensitivity may itself be state-dependent, but proxies and models are both consistent with significant increases in fast sensitivity with increasing temperature.superrotation | hyperthermal T he early Paleogene (∼65-35 Mya) was the most recent time when the atmospheric carbon dioxide (CO 2 ) concentration was in the ≥1,000-ppm range that may reoccur over the next several centuries (1). Study of this period may therefore provide constraints on climate sensitivity, broadly defined as the global mean temperature response to radiative forcing, which are useful for climate change prediction (2, 3). On the other hand, analogies between early Paleogene and future climates are not straightforward because so many other variables apart from CO 2 have also changed (4), and because climate sensitivity may change across different climate states (3,5). Given the crucial role that paleoclimate data from past greenhouse climates play in informing the debates about future climate change (6, 7), an investigation of the strengths and limitations of using such data to make inferences about climate sensitivity is in order.Recent progress in reconstructing the early Paleogene has brought an across-the-board upward revision of surface temperature estimates. Tropical sea surface temperatures (SSTs), previously thought to be similar to or even cooler than modern SSTs, were 3-10°C warmer than today (8-12), although uncertainty on these values remains large (13). Extratropical surface temperature...

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“…S2). There is observational support for the notion that such a shift in storm tracks is associated with positive cloud feedback (54).…”

Section: Discussionmentioning

confidence: 93%

State-dependent climate sensitivity in past warm climates and its implications for future climate projections

Caballero

Huber

2013

Proc. Natl. Acad. Sci. U.S.A.

201

195

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“…Cloud thermodynamic phase affects radiative forcing by modulating absorption of incoming solar radiation, particle evolution, and lifetime (Ehrlich et al, 2008;. Previous satellite observational studies have shown that clouds are shifting poleward in the northern and southern hemispheric extratropical storm tracks (Bender et al, 2012;Marvel et al, 2015;Norris et al, 2016). Within these shifting storm tracks, climate model experiments with forcing from increased CO 2 have shown losses of cloud ice phase and gains of cloud liquid phase McCoy et al, 2015).…”

Section: Introductionmentioning

confidence: 99%

Global spectroscopic survey of cloud thermodynamic phase at high spatial resolution, 2005–2015

et al. 2018

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Abstract. The distribution of ice, liquid, and mixed phase clouds is important for Earth's planetary radiation budget, impacting cloud optical properties, evolution, and solar reflectivity. Most remote orbital thermodynamic phase measurements observe kilometer scales and are insensitive to mixed phases. This under-constrains important processes with outsize radiative forcing impact, such as spatial partitioning in mixed phase clouds. To date, the fine spatial structure of cloud phase has not been measured at global scales. Imaging spectroscopy of reflected solar energy from 1.4 to 1.8 µm can address this gap: it directly measures ice and water absorption, a robust indicator of cloud top thermodynamic phase, with spatial resolution of tens to hundreds of meters. We report the first such global high spatial resolution survey based on data from 2005 to 2015 acquired by the Hyperion imaging spectrometer onboard NASA's Earth Observer 1 (EO-1) spacecraft. Seasonal and latitudinal distributions corroborate observations by the Atmospheric Infrared Sounder (AIRS). For extratropical cloud systems, just 25 % of variance observed at GCM grid scales of 100 km was related to irreducible measurement error, while 75 % was explained by spatial correlations possible at finer resolutions.

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“…Wylie et al, 2005;Dim et al, 2011;Bender et al, 2012;Marvel et al, 2015;Norris et al, 2016;Manaster et al, 2017) suggest that climate change signals may be observable within the satellite era. There is a notable absence of published studies regarding trends in ice microphysics.…”

Section: Introductionmentioning

confidence: 99%

Ice cloud microphysical trends observed by the Atmospheric Infrared Sounder

et al. 2018

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Abstract. We use the Atmospheric Infrared Sounder (AIRS) version 6 ice cloud property and thermodynamic phase retrievals to quantify variability and 14-year trends in ice cloud frequency, ice cloud top temperature (T ci ), ice optical thickness (τ i ) and ice effective radius (r ei ). The trends in ice cloud properties are shown to be independent of trends in information content and χ 2 . Statistically significant decreases in ice frequency, τ i , and ice water path (IWP) are found in the SH and NH extratropics, but trends are of much smaller magnitude and statistically insignificant in the tropics. However, statistically significant increases in r ei are found in all three latitude bands. Perturbation experiments consistent with estimates of AIRS radiometric stability fall significantly short of explaining the observed trends in ice properties, averaging kernels, and χ 2 trends. Values of r ei are larger at the tops of opaque clouds and exhibit dependence on surface wind speed, column water vapour (CWV) and surface temperature (T sfc ) with changes up to 4-5 µm but are only 1.9 % of all ice clouds. Non-opaque clouds exhibit a much smaller change in r ei with respect to CWV and T sfc . Comparisons between DARDAR and AIRS suggest that r ei is smallest for singlelayer cirrus, larger for cirrus above weak convection, and largest for cirrus above strong convection at the same cloud top temperature. This behaviour is consistent with enhanced particle growth from radiative cooling above convection or large particle lofting from strong convection.

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Changes in extratropical storm track cloudiness 1983–2008: observational support for a poleward shift

Cited by 158 publications

References 49 publications

State-dependent climate sensitivity in past warm climates and its implications for future climate projections

State-dependent climate sensitivity in past warm climates and its implications for future climate projections

Global spectroscopic survey of cloud thermodynamic phase at high spatial resolution, 2005–2015

Ice cloud microphysical trends observed by the Atmospheric Infrared Sounder

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