Climate dynamics

Climate Stabilization Targets: Emissions, Concentrations, and Impacts over Decades to Millennia

National Academies Press, 2011

Authors:

Committee on Stabilization Targets for Atmospheric Greenhouse Gas Concentrations, Board on Atmospheric Sciences and Climate, Division on Earth and Life Studies, National Research Council

Abstract:

The book quantifies the outcomes of different stabilization targets for greenhouse gas concentrations using analyses and information drawn from the scientific literature.

A PALETTE OF CLIMATES FOR GLIESE 581g

The Astrophysical Journal Letters American Astronomical Society 726:1 (2011) l8

Influence of the quasi-biennial oscillation and El Nio-Southern Oscillation on the frequency of sudden stratospheric warmings

Journal of Geophysical Research Atmospheres 116:20 (2011)

Authors:

JH Richter, K Matthes, N Calvo, LJ Gray

Abstract:

Stratospheric sudden warmings (SSWs) are a major source of variability during Northern Hemisphere winter. The frequency of occurrence of SSWs is influenced by El Nio-Southern Oscillation (ENSO), the quasi-biennial oscillation (QBO), the 11 year solar cycle, and volcanic eruptions. This study investigates the role of ENSO and the QBO on the frequency of SSWs using the National Center for Atmospheric Research's Whole Atmosphere Community Climate Model, version 3.5 (WACCM3.5). In addition to a control simulation, WACCM3.5 simulations with different combinations of natural variability factors such as the QBO and variable sea surface temperatures (SSTs) are performed to investigate the role of QBO and ENSO. Removing only one forcing, variable SSTs or QBO, yields a SSW frequency similar to that in the control experiment; however, removing both forcings results in a significantly decreased SSW frequency. These results imply nonlinear interactions between ENSO and QBO signals in the polar stratosphere during Northern Hemisphere winter. This study also suggests that ENSO and QBO force SSWs differently. The QBO forces SSW events that are very intense and whose impact on the stratospheric temperature can be seen between December and June, whereas ENSO forces less intense SSWs whose response is primarily confined to the months of January, February, and March. The effects of SSWs on the stratospheric background climate is also addressed here. Copyright 2011 by the American Geophysical Union.

Infrared radiation and planetary temperature

Physics Today AIP Publishing 64:1 (2011) 33-38

Multimodel climate and variability of the stratosphere

Journal of Geophysical Research Atmospheres 116:5 (2011)

Authors:

N Butchart, AJ Charlton-Perez, I Cionni, SC Hardiman, PH Haynes, K Krüger, PJ Kushner, PA Newman, SM Osprey, J Perlwitz, M Sigmond, L Wang, H Akiyoshi, J Austin, S Bekki, A Baumgaertner, P Braesicke, C Brhl, M Chipperfield, M Dameris, S Dhomse, V Eyring, R Garcia, H Garny, P Jöckel, JF Lamarque, M Marchand, M Michou, O Morgenstern, T Nakamura, S Pawson, D Plummer, J Pyle, E Rozanov, J Scinocca, TG Shepherd, K Shibata, D Smale, H Teyssèdre, W Tian, D Waugh, Y Yamashita

Abstract:

The stratospheric climate and variability from simulations of sixteen chemistry-climate models is evaluated. On average the polar night jet is well reproduced though its variability is less well reproduced with a large spread between models. Polar temperature biases are less than 5 K except in the Southern Hemisphere (SH) lower stratosphere in spring. The accumulated area of low temperatures responsible for polar stratospheric cloud formation is accurately reproduced for the Antarctic but underestimated for the Arctic. The shape and position of the polar vortex is well simulated, as is the tropical upwelling in the lower stratosphere. There is a wide model spread in the frequency of major sudden stratospheric warnings (SSWs), late biases in the breakup of the SH vortex, and a weak annual cycle in the zonal wind in the tropical upper stratosphere. Quantitatively, "metrics" indicate a wide spread in model performance for most diagnostics with systematic biases in many, and poorer performance in the SH than in the Northern Hemisphere (NH). Correlations were found in the SH between errors in the final warming, polar temperatures, the leading mode of variability, and jet strength, and in the NH between errors in polar temperatures, frequency of major SSWs, and jet strength. Models with a stronger QBO have stronger tropical upwelling and a colder NH vortex. Both the qualitative and quantitative analysis indicate a number of common and long-standing model problems, particularly related to the simulation of the SH and stratospheric variability. Copyright 2011 by the American Geophysical Union.