Your search keyword '"Butchart N"' showing total 4 results

1. The Effect of a Well-Resolved Stratosphere on Surface Climate : Differences between CMIP5 Simulations with High and Low Top Versions of the Met Office Climate Model

Author

Hardiman, S. C., Butchart, N., Hinton, T. J., Osprey, S. M., and Gray, L. J.

Published

2012

2. Evaluation of the Quasi‐Biennial Oscillation in global climate models for the SPARC QBO‐initiative.

Author

Bushell, A. C., Anstey, J. A., Butchart, N., Kawatani, Y., Osprey, S. M., Richter, J. H., Serva, F., Braesicke, P., Cagnazzo, C., Chen, C.‐C., Chun, H.‐Y., Garcia, R. R., Gray, L. J., Hamilton, K., Kerzenmacher, T., Kim, Y.‐H., Lott, F., McLandress, C., Naoe, H., and Scinocca, J.

Subjects

QUASI-biennial oscillation (Meteorology), ATMOSPHERIC models, GENERAL circulation model, OCEAN temperature, GRAVITY waves, OSCILLATIONS

Abstract

Quasi‐biennial oscillations (QBOs) in thirteen atmospheric general circulation models forced with both observed and annually repeating sea surface temperatures (SSTs) are evaluated. In most models the QBO period is close to, but shorter than, the observed period of 28 months. Amplitudes are within ±20% of the observed QBO amplitude at 10 hPa, but typically about half of that observed at lower altitudes (50 and 70 hPa). For almost all models, the oscillation's amplitude profile shows an overall upward shift compared to reanalysis and its meridional extent is too narrow. Asymmetry in the duration of eastward and westward phases is reasonably well captured, though not all models replicate the observed slowing of the descending westward shear. Westward phases are generally too weak, and most models have an eastward time mean wind bias throughout the depth of the QBO. The intercycle period variability is realistic and in some models is enhanced in the experiment with observed SSTs compared to the experiment with repeated annual cycle SSTs. Mean periods are also sensitive to this difference between SSTs, but only when parametrized non‐orographic gravity wave (NOGW) sources are coupled to tropospheric parameters and not prescribed with a fixed value. Overall, however, modelled QBOs are very similar whether or not the prescribed SSTs vary interannually. A portrait of the overall ensemble performance is provided by a normalized grading of QBO metrics. To simulate a QBO, all but one model used parametrized NOGWs, which provided the majority of the total wave forcing at altitudes above 70 hPa in most models. Hence the representation of NOGWs either explicitly or through parametrization is still a major uncertainty underlying QBO simulation in these present‐day experiments. [ABSTRACT FROM AUTHOR]

Published

2022

3. The equatorial stratospheric semiannual oscillation and time‐mean winds in QBOi models.

Author

Smith, A. K., Holt, L. A., Garcia, R. R., Anstey, J. A., Serva, F., Butchart, N., Osprey, S., Bushell, A. C., Kawatani, Y., Kim, Y.‐H., Lott, F., Braesicke, P., Cagnazzo, C., Chen, C.‐C., Chun, H.‐Y., Gray, L., Kerzenmacher, T., Naoe, H., Richter, J., and Versick, S.

Subjects

QUASI-biennial oscillation (Meteorology), ZONAL winds, OCEAN waves, ATMOSPHERIC models, OSCILLATIONS, GRAVITY waves

Abstract

The Quasi‐Biennial Oscillation initiative (QBOi) is a model intercomparison programme that specifically targets simulation of the QBO in current global climate models. Eleven of the models or model versions that participated in a QBOi intercomparison study have upper boundaries in or above the mesosphere and therefore simulate the region where the stratopause semiannual oscillation (SAO) is the dominant mode of variability of zonal winds in the tropical upper stratosphere. Comparisons of the SAO simulations in these models are presented here. These show that the model simulations of the amplitudes and phases of the SAO in zonal‐mean zonal wind near the stratopause agree well with the information derived from available observations. However, most of the models simulate time‐average zonal winds that are more westward than determined from observations, in some cases by several tens of m·s–1. Validation of wave activity in the models is hampered by the limited observations of tropical waves in the upper stratosphere but suggests a deficit of eastward forcing either by large‐scale waves, such as Kelvin waves, or by gravity waves. [ABSTRACT FROM AUTHOR]

Published

2022

4. Large Impacts, Past and Future, of Ozone‐Depleting Substances on Brewer‐Dobson Circulation Trends: A Multimodel Assessment.

Author

Polvani, L. M., Michou, M., Morgenstern, O., Oman, L. D., Plummer, D. A., Stone, K. A., Wang, L., Kinnison, D., Abalos, M., Butchart, N., Chipperfield, M. P., Dhomse, S. S., Dameris, M., Jöckel, P., and Deushi, M.

Subjects

OZONE layer depletion, STRATOSPHERIC circulation, GREENHOUSE gases, ATMOSPHERIC models, ANTHROPOGENIC effects on nature

Abstract

Substantial increases in the atmospheric concentration of well‐mixed greenhouse gases (notably CO2), such as those projected to occur by the end of the 21st century under large radiative forcing scenarios, have long been known to cause an acceleration of the Brewer‐Dobson circulation (BDC) in climate models. More recently, however, several single‐model studies have proposed that ozone‐depleting substances might also be important drivers of BDC trends. As these studies were conducted with different forcings over different periods, it is difficult to combine them to obtain a robust quantitative picture of the relative importance of ozone‐depleting substances as drivers of BDC trends. To this end, we here analyze—over identical past and future periods—the output from 20 similarly forced models, gathered from two recent chemistry‐climate modeling intercomparison projects. Our multimodel analysis reveals that ozone‐depleting substances are responsible for more than half of the modeled BDC trends in the two decades 1980–2000. We also find that, as a consequence of the Montreal Protocol, decreasing concentrations of ozone‐depleting substances in coming decades will strongly decelerate the BDC until the year 2080, reducing the age‐of‐air trends by more than half, and will thus substantially mitigate the impact of increasing CO2. As ozone‐depleting substances impact BDC trends, primarily, via the depletion/recovery of stratospheric ozone over the South Pole, they impart seasonal and hemispheric asymmetries to the trends which may offer opportunities for detection in coming decades. Key Points: Impacts of ozone‐depleting substances (ODS) on Brewer‐Dobson circulation trends are analyzed in 20 chemistry‐climate modelsFor the period 1980–2000 ODS have contributed more than half (roughly 60%) of the stratospheric age‐of‐air trendsFor the period 2000–2080 models show that decreasing ODS levels will substantially decelerate the BDC [ABSTRACT FROM AUTHOR]

Published

2019