Abstract
Abstract. We examine the skill of a new approach to climate field reconstructions (CFRs) using an online paleoclimate data assimilation (PDA) method. Several recent studies have foregone climate model forecasts during assimilation due to the computational expense of running coupled global climate models (CGCMs) and the relatively low skill of these forecasts on longer timescales. Here we greatly diminish the computational cost by employing an empirical forecast model (linear inverse model, LIM), which has been shown to have skill comparable to CGCMs for forecasting annual-to-decadal surface temperature anomalies. We reconstruct annual-average 2 m air temperature over the instrumental period (1850–2000) using proxy records from the PAGES 2k Consortium Phase 1 database; proxy models for estimating proxy observations are calibrated on GISTEMP surface temperature analyses. We compare results for LIMs calibrated using observational (Berkeley Earth), reanalysis (20th Century Reanalysis), and CMIP5 climate model (CCSM4 and MPI) data relative to a control offline reconstruction method. Generally, we find that the usage of LIM forecasts for online PDA increases reconstruction agreement with the instrumental record for both spatial fields and global mean temperature (GMT). Specifically, the coefficient of efficiency (CE) skill metric for detrended GMT increases by an average of 57 % over the offline benchmark. LIM experiments display a common pattern of skill improvement in the spatial fields over Northern Hemisphere land areas and in the high-latitude North Atlantic–Barents Sea corridor. Experiments for non-CGCM-calibrated LIMs reveal region-specific reductions in spatial skill compared to the offline control, likely due to aspects of the LIM calibration process. Overall, the CGCM-calibrated LIMs have the best performance when considering both spatial fields and GMT. A comparison with the persistence forecast experiment suggests that improvements are associated with the linear dynamical constraints of the forecast and not simply persistence of temperature anomalies.
Highlights
Climate field reconstructions (CFRs) aim to provide essential information on climate variability beyond the instrumental record
Best skill is achieved between the a values of 0.7 to 0.9, with a steep drop in validation skill as a approaches unity due to filter divergence
The coefficient of efficiency (CE) scores for all linear inverse model (LIM) experiments show significant increases compared to the offline CE, while the persistence, 20th Century Reanalysis (20CR), Community Climate System Model v4 (CCSM4), and MPI experiments show significant increases in correlation
Summary
Climate field reconstructions (CFRs) aim to provide essential information on climate variability beyond the instrumental record. Due to the expense of performing coupled global climate model (CGCM) simulations and relatively low forecast skill, the initial EnKF adaptation for PDA does not use a forecast and instead reconstructs each time period independently using climatological data This is known as an offline approach. Possible reasons for the lack of improvement include low skill for regional decadal forecasts of temperature and issues related to ocean initialization for each decadal interval These results suggest that neither the simple persistence forecast nor a small ensemble of decadal CGCM forecasts add significant information to CFRs. In order to test the viability of a more traditional EnKF method, we require the ability to perform annual forecasts for longer time spans (the past millennium) and in large ensembles ( ∼ 100 members).
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