Abstract
The connections between the Madden–Julian Oscillation (MJO) and the Arctic Oscillation (AO) are examined in both observations and model forecasts. In the observations, the time-lag composites are carried out for AO indices and anomalies of 1,000-hPa geopotential height after an active or inactive initial MJO. The results show that when the AO is in its positive (negative) phase at the initial time, the AO activity is generally enhanced (weakened) after an active MJO. Reforecast data of the 11 operational global circulation models from the Sub-seasonal to Seasonal (S2S) Prediction Project are further used to examine the relationship between MJO activity and AO prediction. When the AO is in its positive phase on the initial day of the S2S prediction, an initial active MJO can generally improve the AO prediction skill in most of the models. This is consistent with results found in the observations that a leading MJO can enhance the AO activity. However, when the AO is in its negative phase, the relationship between the MJO and AO prediction is not consistent among the 11 models. Only a few S2S models provide results that agree with the observations. Furthermore, the S2S prediction skill of the AO is examined in different MJO phases. There is a significantly positive relationship between the MJO-related AO activity and the AO prediction skill. When the AO activity is strong (weak) in an MJO phase, including the inactive MJO, the models tend to have a high (low) AO prediction skill. For example, no matter what phase the initial AO is in, the AO prediction skill is generally high in MJO phase 7, in which the AO activity is generally strong. Thus, the MJO is an important predictability source for the AO forecast in the S2S models.
Highlights
The Madden–Julian Oscillation (MJO; Madden and Julian, 1971; Madden and Julian, 1972) is taken as a predictability source for the sub-seasonal to seasonal (S2S; 10–90 days) climate forecast (Ferranti et al, 1990; Jones et al, 2004; Reichler and Roads, 2005; Zhang et al, 2013; Jones and Dudhia, 2017; Specq and Batté, 2020)
As a substantial condition for the S2S climate prediction in the numerical model, the initial state of the atmosphere carries lots of signals of use. How do they interact with predictands that we care, and which one can be a predictability source for S2S prediction? Answering those two questions can help us to improve the understanding of S2S prediction
The impacts of MJO on the Arctic Oscillation (AO) prediction in the S2S models are explored in the present study
Summary
The Madden–Julian Oscillation (MJO; Madden and Julian, 1971; Madden and Julian, 1972) is taken as a predictability source for the sub-seasonal to seasonal (S2S; 10–90 days) climate forecast (Ferranti et al, 1990; Jones et al, 2004; Reichler and Roads, 2005; Zhang et al, 2013; Jones and Dudhia, 2017; Specq and Batté, 2020). The significantly positive relationship indicates that when the MJO-related AO activity is strong in the observations, there tends to be a high prediction skill in most of the S2S models. The forecast in phase 2 on day 15 has less skill among all the phases in the three models Those findings from the prediction skill are generally consistent with the MJO-related AO activity in the observations (Figures 6A–C). In phases 2, 4, and 5, the skill is generally smaller than or close to that in phase 0 in the three models, except in phases 2, 4, and 5 on day 15 in CMA These findings further present that AO prediction skill is related to the MJO activity, which agrees with that in the observations (Figures 6D–F). It is still found that when the MJO activity enlarges the AO strength, it tends to lead to a large prediction skill of the AO in the S2S models
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