Predictability of weather and climate

Impact of Initial Conditions versus External Forcing in Decadal Climate Predictions: A Sensitivity Experiment*

Journal of Climate American Meteorological Society 28:11 (2015) 4454-4470

Authors:

Susanna Corti, Tim Palmer, Magdalena Balmaseda, Antje Weisheimer, Sybren Drijfhout, Nick Dunstone, Wilco Hazeleger, Jürgen Kröger, Holger Pohlmann, Doug Smith, Jin-Song von Storch, Bert Wouters

Stochastic and Perturbed Parameter Representations of Model Uncertainty in Convection Parameterization*

Journal of the Atmospheric Sciences American Meteorological Society 72:6 (2015) 2525-2544

Authors:

HM Christensen, IM Moroz, TN Palmer

Architectures and Precision Analysis for Modelling Atmospheric Variables with Chaotic Behaviour

Institute of Electrical and Electronics Engineers (IEEE) (2015) 171-178

Authors:

Francis P Ruwssell, Peter D Düben, Xinyu Niu, Wayne Luk, TN Palmer

Opportunities for energy efficient computing: A study of inexact general purpose processors for high-performance and big-data applications

2014 Design, Automation & Test in Europe Conference & Exhibition (DATE) EDAA (2015) 764-769

Authors:

Peter Duben, Jeremy Schlachter, Parishkrati, Sreelatha Yenugula, John Augustine, Christian Enz, K Palem, TN Palmer

Simulating weather regimes: impact of stochastic and perturbed parameter schemes in a simple atmospheric model

Climate Dynamics 44:7-8 (2015) 2195-2214

Authors:

HM Christensen, IM Moroz, TN Palmer

Abstract:

Representing model uncertainty is important for both numerical weather and climate prediction. Stochastic parametrisation schemes are commonly used for this purpose in weather prediction, while perturbed parameter approaches are widely used in the climate community. The performance of these two representations of model uncertainty is considered in the context of the idealised Lorenz ’96 system, in terms of their ability to capture the observed regime behaviour of the system. These results are applicable to the atmosphere, where evidence points to the existence of persistent weather regimes, and where it is desirable that climate models capture this regime behaviour. The stochastic parametrisation schemes considerably improve the representation of regimes when compared to a deterministic model: both the structure and persistence of the regimes are found to improve. The stochastic parametrisation scheme represents the small scale variability present in the full system, which enables the system to explore a larger portion of the system’s attractor, improving the simulated regime behaviour. It is important that temporally correlated noise is used in the stochastic parametrisation—white noise schemes performed similarly to the deterministic model. In contrast, the perturbed parameter ensemble was unable to capture the regime structure of the attractor, with many individual members exploring only one regime. This poor performance was not evident in other climate diagnostics. Finally, a ‘climate change’ experiment was performed, where a change in external forcing resulted in changes to the regime structure of the attractor. The temporally correlated stochastic schemes captured these changes well.