Professor Lesley Gray

CMIP5 Simulations of Climate Following Volcanic

Journal of Geophysical Research: Atmospheres American Geophysical Union (2012)

Authors:

S Driscoll, A Bozzo, Lesley J Gray, A Robock, G Stenchikov

Trends in Austral jet position in ensembles of

Journal of Geophysical Research: atmospheres American Geophysical Union (2012)

Authors:

LJ Wilcox, AJ Charlton-Perez, LJ Gray

Correction to “Solar influences on climate”

Reviews of Geophysics American Geophysical Union (AGU) 50:1 (2012)

Authors:

LJ Gray, J Beer, M Geller, JD Haigh, M Lockwood, K Matthes, U Cubasch, D Fleitmann, G Harrison, L Hood, J Luterbacher, GA Meehl, D Shindell, B van Geel, W White

Coupled Model Intercomparison Project 5 (CMIP5) simulations of climate following volcanic eruptions

Journal of Geophysical Research Atmospheres 117:17 (2012)

Authors:

S Driscoll, A Bozzo, LJ Gray, A Robock, G Stenchikov

Abstract:

The ability of the climate models submitted to the Coupled Model Intercomparison Project 5 (CMIP5) database to simulate the Northern Hemisphere winter climate following a large tropical volcanic eruption is assessed. When sulfate aerosols are produced by volcanic injections into the tropical stratosphere and spread by the stratospheric circulation, it not only causes globally averaged tropospheric cooling but also a localized heating in the lower stratosphere, which can cause major dynamical feedbacks. Observations show a lower stratospheric and surface response during the following one or two Northern Hemisphere (NH) winters, that resembles the positive phase of the North Atlantic Oscillation (NAO). Simulations from 13 CMIP5 models that represent tropical eruptions in the 19th and 20th century are examined, focusing on the large-scale regional impacts associated with the large-scale circulation during the NH winter season. The models generally fail to capture the NH dynamical response following eruptions. They do not sufficiently simulate the observed post-volcanic strengthened NH polar vortex, positive NAO, or NH Eurasian warming pattern, and they tend to overestimate the cooling in the tropical troposphere. The findings are confirmed by a superposed epoch analysis of the NAO index for each model. The study confirms previous similar evaluations and raises concern for the ability of current climate models to simulate the response of a major mode of global circulation variability to external forcings. This is also of concern for the accuracy of geoengineering modeling studies that assess the atmospheric response to stratosphere-injected particles. © 2012. American Geophysical Union. All Rights Reserved.

Trends in Austral jet position in ensembles of high- and low-top CMIP5 models

Journal of Geophysical Research Atmospheres 117:13 (2012)

Authors:

LJ Wilcox, AJ Charlton-Perez, LJ Gray

Abstract:

Trends in the position of the DJF Austral jet have been analyzed for multimodel ensemble simulations of a subset of high- and low-top models for the periods 1960-2000, 2000-2050, and 2050-2098 under the CMIP5 historical, RCP4.5, and RCP8.5 scenarios. Comparison with ERA-Interim, CFSR and the NCEP/NCAR reanalysis shows that the DJF and annual mean jet positions in CMIP5 models are equatorward of reanalyses for the 1979-2006 mean. Under the RCP8.5 scenario, the mean jet position in the high-top models moves 3 degrees poleward of its 1860-1900 position by 2098, compared to just over 2 degrees for the low-top models. Changes in jet position are linked to changes in the meridional temperature gradient. Compared to low-top models, the high-top models predict greater warming in the tropical upper troposphere due to increased greenhouse gases for all periods considered: up to 0.28K/decade more in the period 2050-2098 under the RCP8.5 scenario. Larger polar lower-stratospheric cooling is seen in high-top models: -1.64K/decade compared to -1.40K/decade in the period 1960-2000, mainly in response to ozone depletion, and -0.41K/decade compared to -0.12K/decade in the period 2050-2098, mainly in response to increases in greenhouse gases. Analysis suggests that there may be a linear relationship between the trend in jet position and meridional temperature gradient, even under strong forcing. There were no clear indications of an approach to a geometric limit on the absolute magnitude of the poleward shift by 2100. © 2012. American Geophysical Union. All Rights Reserved.