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Stationary Wave Reflection as a Mechanism for Zonalizing the Atlantic Winter Jet at the LGM (2016)

Löfverström, Marcus ; Caballero, Rodrigo ; Nilsson, Johan ; [et al.]

American Meteorological Society

In: Journal of the Atmospheric Sciences. 2016; 73(8): 3329-3342. Published 2016 Aug 01. doi: 10.1175/jas-d-15-0295.1.

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Publication Date: 2016-08-01

Description: Current estimates of the height of the Laurentide Ice Sheet (LIS) at the Last Glacial Maximum (LGM) range from around 3000 to 4500 m. Modeling studies of the LGM, using low-end estimates of the LIS height, show a relatively weak and northeastward-tilted winter jet in the North Atlantic, similar to the modern jet, while simulations with high-end LIS elevations show a much more intense and zonally oriented jet. Here, an explanation for this response of the Atlantic circulation is sought using a sequence of LGM simulations spanning a broad range of LIS elevations. It is found that increasing LIS height favors planetary wave breaking and nonlinear reflection in the subtropical North Atlantic. For high LIS elevations, planetary wave reflection becomes sufficiently prevalent that a poleward-directed flux of wave activity appears in the climatology over the midlatitude North Atlantic. This entails a zonalization of the stationary wave phase lines and thus of the midlatitude jet.

Print ISSN: 0022-4928

Electronic ISSN: 1520-0469

Topics: Geography , Geosciences , Physics

Published by American Meteorological Society

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The North American Cordillera—An Impediment to Growing the Continent-Wide Laurentide Ice Sheet (2015)

Löfverström, Marcus ; Liakka, Johan ; Kleman, Johan

American Meteorological Society

In: Journal of Climate. 2015; 28(23): 9433-9450. Published 2015 Dec 01. doi: 10.1175/jcli-d-15-0044.1.

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Publication Date: 2015-12-01

Description: This study examines the evolution of a continental-scale ice sheet on a triangular representation of North America, with and without the influence of the Cordilleran region. Simulations are conducted using a comprehensive atmospheric general circulation model asynchronously coupled to a three-dimensional thermomechanical ice-sheet model. The atmospheric state is updated for every 2 × 106 km3 increase in ice volume, and the coupled model is integrated to steady state. In the first experiment a flat continent with no background topography is used. The ice sheet evolves fairly zonally symmetric, and the equilibrium state is continent-wide and has the highest point in the center of the continent. This equilibrium ice sheet forces an anticyclonic circulation that results in relatively warmer (cooler) summer surface temperatures in the northwest (southeast), owing to warm (cold) air advection and radiative heating due to reduced cloudiness. The second experiment includes a simplified representation of the Cordilleran region. The ice sheet’s equilibrium state is here structurally different from the flat continent case; the center of mass is strongly shifted to the east and the interior of the continent remains ice free—an outline broadly resembling the geologically determined ice margin in Marine Isotope Stage 4. The limited glaciation in the continental interior is the result of warm summer surface temperatures primarily due to stationary waves and radiative feedbacks.

Print ISSN: 0894-8755

Electronic ISSN: 1520-0442

Topics: Geography , Geosciences , Physics

Published by American Meteorological Society

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