Your search keyword '"Andrews, Martin B."' showing total 7 results

1. Influence of the Quasi‐Biennial Oscillation on tropical convection and its teleconnection to the midlatitudes in boreal winter

Author

Andrews, Martin B., primary, Knight, Jeff R., additional, Scaife, Adam A., additional, and Wicker, Wolfgang, additional

Published

2024

2. Statistics of sudden stratospheric warmings using a large model ensemble

Author

Ineson, Sarah, primary, Dunstone, Nick J., additional, Scaife, Adam A., additional, Andrews, Martin B., additional, Lockwood, Julia F., additional, and Pang, Bo, additional

Published

2023

3. Assessing the representation of South American monsoon features in Brazil and U.K. climate model simulations

Author

Coelho, Caio A.S., de Souza, Dayana C., Kubota, Paulo Y., Cavalcanti, Iracema F.A., Baker, Jessica C.A., Figueroa, Silvio N., Firpo, Mári A.F., Guimarães, Bruno S., Costa, Simone M.S., Gonçalves, Layrson J.M., Bonatti, José P., Sampaio, Gilvan, Klingaman, Nicholas P., Chevuturi, Amulya, Andrews, Martin B., Coelho, Caio A.S., de Souza, Dayana C., Kubota, Paulo Y., Cavalcanti, Iracema F.A., Baker, Jessica C.A., Figueroa, Silvio N., Firpo, Mári A.F., Guimarães, Bruno S., Costa, Simone M.S., Gonçalves, Layrson J.M., Bonatti, José P., Sampaio, Gilvan, Klingaman, Nicholas P., Chevuturi, Amulya, and Andrews, Martin B.

Abstract

This paper assesses how well the CPTEC/INPE Brazilian Global Atmospheric Model (BAM-1.2) and the atmospheric component of the UK Met Office Hadley Centre Global Environment Model (HadGEM3-GC3.1) represent the main South American monsoon features. Climatological (1981–2010) ensemble means of Atmospheric Model Intercomparison Project (AMIP)-type climate simulations are evaluated. The assessment evaluated the models’ ability to represent the South America austral summer and winter precipitation contrast and associated circulation, key South American monsoon system elements, the association between south-east Brazil and South America precipitation, and climatological (1997/1998 to 2013/2014) distributions of rainy season onset and demise dates over south-east Brazil (15°S–25°S, 40°W–50°W) and the core monsoon region (10°S–20°S, 45°W–55°W). Despite some identified deficiencies, both models depict the monsoon region and represent the main features, including (1) the north-west–south-east precipitation band and associated ascending motion over central South America; (2) the upper-level Bolivian High and the north-east South America trough during the summer; (3) the lower-level South Atlantic and Pacific subtropical anti-cyclones and (4) the low-level jet east of the Andes. Both models represent upper-level divergence and lower-level convergence over the core monsoon region, and upper-level convergence and lower-level divergence over the Pacific and Atlantic anti-cyclones associated with the regional Walker circulation during the pre-monsoon (spring) and peak monsoon (summer) seasons. Convection over South America is weaker in BAM-1.2 than observed, consistent with continental precipitation deficit. The models reproduce the dipole-like precipitation pattern between south-east Brazil and south-eastern South America during the austral summer but overestimate these patterns spatial extent over the South Atlantic. Both models simulate the main observed climatological features o

Published

2022

4. Mechanisms of influence of the Semi‐Annual Oscillation on stratospheric sudden warmings

Author

Gray, Lesley J., primary, Lu, Hua, additional, Brown, Matthew J., additional, Knight, Jeff R., additional, and Andrews, Martin B., additional

Published

2022

5. Assessing the representation of South American monsoon features in Brazil and U.K. climate model simulations

Author

Coelho, Caio A. S., primary, Souza, Dayana C., additional, Kubota, Paulo Y., additional, Cavalcanti, Iracema F. A., additional, Baker, Jessica C. A., additional, Figueroa, Silvio N., additional, Firpo, Mári A. F., additional, Guimarães, Bruno S., additional, Costa, Simone M. S., additional, Gonçalves, Layrson J. M., additional, Bonatti, José P., additional, Sampaio, Gilvan, additional, Klingaman, Nicholas P., additional, Chevuturi, Amulya, additional, and Andrews, Martin B., additional

Published

2021

6. Assessing the representation of South American monsoon features in Brazil and U.K. climate model simulations

Author

Coelho, Caio A.S., de Souza, Dayana C., Kubota, Paulo Y., Cavalcanti, Iracema F.A., Baker, Jessica C.A., Figueroa, Silvio N., Firpo, Mári A.F., Guimarães, Bruno S., Costa, Simone M.S., Gonçalves, Layrson J.M., Bonatti, José P., Sampaio, Gilvan, Klingaman, Nicholas P., Chevuturi, Amulya, Andrews, Martin B., Coelho, Caio A.S., de Souza, Dayana C., Kubota, Paulo Y., Cavalcanti, Iracema F.A., Baker, Jessica C.A., Figueroa, Silvio N., Firpo, Mári A.F., Guimarães, Bruno S., Costa, Simone M.S., Gonçalves, Layrson J.M., Bonatti, José P., Sampaio, Gilvan, Klingaman, Nicholas P., Chevuturi, Amulya, and Andrews, Martin B.

Abstract

This paper assesses how well the CPTEC/INPE Brazilian Global Atmospheric Model (BAM-1.2) and the atmospheric component of the UK Met Office Hadley Centre Global Environment Model (HadGEM3-GC3.1) represent the main South American monsoon features. Climatological (1981–2010) ensemble means of Atmospheric Model Intercomparison Project (AMIP)-type climate simulations are evaluated. The assessment evaluated the models’ ability to represent the South America austral summer and winter precipitation contrast and associated circulation, key South American monsoon system elements, the association between south-east Brazil and South America precipitation, and climatological (1997/1998 to 2013/2014) distributions of rainy season onset and demise dates over south-east Brazil (15°S–25°S, 40°W–50°W) and the core monsoon region (10°S–20°S, 45°W–55°W). Despite some identified deficiencies, both models depict the monsoon region and represent the main features, including (1) the north-west–south-east precipitation band and associated ascending motion over central South America; (2) the upper-level Bolivian High and the north-east South America trough during the summer; (3) the lower-level South Atlantic and Pacific subtropical anti-cyclones and (4) the low-level jet east of the Andes. Both models represent upper-level divergence and lower-level convergence over the core monsoon region, and upper-level convergence and lower-level divergence over the Pacific and Atlantic anti-cyclones associated with the regional Walker circulation during the pre-monsoon (spring) and peak monsoon (summer) seasons. Convection over South America is weaker in BAM-1.2 than observed, consistent with continental precipitation deficit. The models reproduce the dipole-like precipitation pattern between south-east Brazil and south-eastern South America during the austral summer but overestimate these patterns spatial extent over the South Atlantic. Both models simulate the main observed climatological features o

Published

2021

7. Implementation of U.K. Earth system models for CMIP6

Author

Sellar, Alistair A., Walton, Jeremy, Jones, Colin G., Wood, Richard, Abraham, Nathan Luke, Andrejczuk, Miroslaw, Andrews, Martin B., Andrews, Timothy, Archibald, Alex T., de Mora, Lee, Dyson, Harold, Elkington, Mark, Ellis, Richard, Florek, Piotr, Good, Peter, Gohar, Laila, Haddad, Stephen, Hardiman, Steven C., Hogan, Emma, Iwi, Alan, Jones, Christopher D., Johnson, Ben, Kelley, Douglas I., Kettleborough, Jamie, Knight, Jeff R., Köhler, Marcus O., Kuhlbrodt, Till, Liddicoat, Spencer, Linova‐Pavlova, Irina, Mizielinski, Matthew S., Morgenstern, Olaf, Mulcahy, Jane, Neininger, Erica, O'Connor, Fiona M., Petrie, Ruth, Ridley, Jeff, Rioual, Jean‐Christophe, Roberts, Malcolm, Robertson, Eddy, Rumbold, Steven, Seddon, Jon, Shepherd, Harry, Shim, Sungbo, Stephens, Ag, Teixiera, Joao C., Tang, Yongming, Williams, Jonny, Wiltshire, Andy, Griffiths, Paul T., Sellar, Alistair A., Walton, Jeremy, Jones, Colin G., Wood, Richard, Abraham, Nathan Luke, Andrejczuk, Miroslaw, Andrews, Martin B., Andrews, Timothy, Archibald, Alex T., de Mora, Lee, Dyson, Harold, Elkington, Mark, Ellis, Richard, Florek, Piotr, Good, Peter, Gohar, Laila, Haddad, Stephen, Hardiman, Steven C., Hogan, Emma, Iwi, Alan, Jones, Christopher D., Johnson, Ben, Kelley, Douglas I., Kettleborough, Jamie, Knight, Jeff R., Köhler, Marcus O., Kuhlbrodt, Till, Liddicoat, Spencer, Linova‐Pavlova, Irina, Mizielinski, Matthew S., Morgenstern, Olaf, Mulcahy, Jane, Neininger, Erica, O'Connor, Fiona M., Petrie, Ruth, Ridley, Jeff, Rioual, Jean‐Christophe, Roberts, Malcolm, Robertson, Eddy, Rumbold, Steven, Seddon, Jon, Shepherd, Harry, Shim, Sungbo, Stephens, Ag, Teixiera, Joao C., Tang, Yongming, Williams, Jonny, Wiltshire, Andy, and Griffiths, Paul T.

Abstract

We describe the scientific and technical implementation of two models for a core set of experiments contributing to the sixth phase of the Coupled Model Intercomparison Project (CMIP6). The models used are the physical atmosphere‐land‐ocean‐sea ice model HadGEM3‐GC3.1 and the Earth system model UKESM1 which adds a carbon‐nitrogen cycle and atmospheric chemistry to HadGEM3‐GC3.1. The model results are constrained by the external boundary conditions (forcing data) and initial conditions. We outline the scientific rationale and assumptions made in specifying these. Notable details of the implementation include an ozone redistribution scheme for prescribed ozone simulations (HadGEM3‐GC3.1) to avoid inconsistencies with the model's thermal tropopause, and land use change in dynamic vegetation simulations (UKESM1) whose influence will be subject to potential biases in the simulation of background natural vegetation. We discuss the implications of these decisions for interpretation of the simulation results. These simulations are expensive in terms of human and CPU resources and will underpin many further experiments; we describe some of the technical steps taken to ensure their scientific robustness and reproducibility.

Published

2020