This study is based on the output of the MPI-ESM version 1.2 developed for the Coupled Model Intercomparison Project 6 . The model runs fully coupled in the LR configuration that uses the atmospheric component ECHAM 6.3.05 with a T63 spatial truncation and 47 atmospheric layers. The atmospheric model is directly coupled with the land model JSBACH 3.20 and uses an interactive carbon cycle, which means atmospheric CO2 reacts to land and ocean carbon fluxes.

The control simulation used in this study is a 1000-year unforced simulation with a preindustrial CO2 concentration of 285 ppm. A total of thirty-five 10-member ensemble simulations are initialized, each starting in January with a run time of 2 years. The unperturbed simulation of the control run is added to the ensembles as the 11th member. Initialization dates are selected manually in order to attain a diversity of ENSO states. The selected dates are grouped into three categories: El Niño, La Niña, or ENSO-neutral.The potential predictability is assessed by using a correlation-based and a distance-based metric. The anomaly correlation coefficient (ACC) is a commonly used metric to measure forecast skill which calculates the correlation between predicted and observed anomalies as 1ACCj,t=cov(f,o)σf⋅σo, where j and t are grid cell and lead time, cov is the covariance, and f and o are the forecast and validation anomalies. Similar to and , the noise in the ACC is reduced by averaging over several ACC values. This is achieved by taking all 11 ensemble members as the validation in turn, while the mean of the remaining ensemble members serves as the forecast. Although the ACC is an intuitive metric which is calculated from all initializations and thus provides a robust estimation of the predictability, it does not allow us to investigate the variability of predictability between initializations. The comparison of predictabilities between initialization is achieved by the use of a distance-based metric which is computed for all initializations individually. The distance-based metric used here is the normalized ensemble variance (V(t)) based on the method proposed by . Predictability is defined as the ensemble variance normalized by the variance of the climatology as 2V(t)=1M∑i=1M[Xi(t)-X‾(t)]2σ2, where t is lead time, M the number of ensemble members, Xi the ith member, X‾ the ensemble mean, and σ2 the variance of the control simulation. In this study, the complement of the normalized ensemble variance is used as Vc(t)=1-V(t). The resulting metric indicates perfect predictability at a value of 1 and an ensemble spread that exceeds the climatological variance for values below zero.

While ACC and Vc allow the estimation of regional predictability, these metrics are not suitable to evaluate the impact of local predictabilities on the predictability of the global carbon cycle. This is due to the disregard of the flux amplitude in the calculation of the metrics. Both of the metrics are prone to producing above-average predictabilities in regions where carbon fluxes are generally low or even close to zero, such as subtropical deserts. Here we propose a weighted predictability metric that allows us to assess local predictabilities with regard to their impact on the predictability of the global carbon cycle. Vc is weighted by using an approach similar to risk assessment, which is calculated as the product of likelihood and impact. Here a weighted predictability wVc is calculated by multiplying Vc with the absolute carbon flux anomaly of the ensemble mean: 3wVc(t)=Vc(t)×|ΔFLUX(t)|.

In order to investigate the drivers of CFpred, the Vc of NPP and Rh are decomposed into components contributing to the predictability of these fluxes similar to an approach used by . They used regression analysis to determine the contribution of environmental variables to the anomalies in GPP and ecosystem respiration. Here the assumptions of are extended from carbon flux anomalies to CFpred: a high CFpred needs to be caused by a high predictability of one or more of its driving environmental variables. Using this assumption, NPPpred and Rhpred are modelled as the response to the predictability of the individual environmental drivers. Regression analysis is used to determine the contribution of the predictability of the environmental variables to NPPpred and Rhpred. The drivers of NPPpred are selected following the drivers of GPP in as two layers of soil moisture (midSOILpred for 19–78 cm depth and deepSOILpred for 79–268 cm depth), air temperature (TEMPpred), and photosynthetically active radiation (PARpred). The drivers of Rhpred are based on the rate modifying factors used in JSBACH to calculate Rh, which are TEMPpred, PRECIPpred, and SOCpred. Although precipitation has no direct relationship with Rh, the Rh submodel used in JSBACH is parameterized using precipitation because of its strong relationship with moisture in the uppermost soil layer where most of the respiration takes place. Instead of SOC, the content of the aboveground acid-hydrolysable carbon pool (here referred to as SOC) is used as a surrogate variable. The contribution of the predictability of the environmental drivers to the CFpred is calculated as 4VcFLUXj,t,i=∑k[aj,tDRIk×VcDRIk,j,t,i]+ϵj,t,i, with VcFLUX being the complementary normalized ensemble variance of NPP or Rh, aDRIk the coefficient of the kth driver (for example TEMPpred), Vc DRI the predictability of the kth driver, and ϵ the residual error term. Grid cell, lead time, and initialization are denoted by the indices j, t, and i. The regression coefficients are calculated by using non-negative least squares for every grid cell and lead time by using the data from all initializations. After fitting the regression model to the data, the individual components of CFpred are calculated as 5VcFLUXi,t,sDRIk=ai,tDRIk×VcDRIk,i,t,s, where VcFLUXDRI describes the amount of predictability of FLUX that can be attributed to the driver k.

The 35 perfect model simulations are used to assess potential NPPpred and Rhpred. Zonal means of the ACC are shown in Fig.  (zonal plots of predictability are limited to 30∘ S to 30∘ N to highlight the areas of high predictability). NPPpred and Rhpred are highest in the tropics between 20∘ N and S, where carbon fluxes are at their global maximum. However, apart from the generally high predictability in the tropics, the patterns of NPPpred and Rhpred differ in several aspects. While the ACC of NPP has a slower temporal decline with values above 0.8 for 2 to 3 months around the Equator, the ACC of Rh drops below 0.5 within the first 2 months for most latitudes. However, Rh shows much higher long-term predictability, especially in the second year of the simulation where Rhpred is much higher than NPPpred.

While both predictability patterns show signs of a seasonal cycle, they are out of phase, with Rhpred distinctly following the wet season and NPPpred appearing to be higher in the dry seasons of the first year. This has a large role in the comparability of NPPpred and Rhpred, since high NPPpred occurs at the time of the seasonal low of NPP fluxes, while high Rhpred is associated with the seasonal high. Another characteristic of the seasonal cycles is their continuity. Rhpred migrates continuously across the zones, while NPPpred demonstrates a sporadic behaviour with a high predictability at around 15∘ N in January to March and another one at 10∘ S from July to September.

The spatial patterns of ACC are shown in Fig.  for March, June, and September of the first year and September of the second year. Rhpred shows a very coherent pattern with a band of high predictability migrating from south to north across all continents. The patterns of NPPpred appear to be less constrained by latitude. Although March predictability is dominated by the northern tropics and subtropics, there are other high-predictability regions based on initial memory, especially at high latitudes. As opposed to Rhpred, there is no high-predictability band moving across the zones. Instead, NPPpred is re-emerging south of the Equator in September in the southern Amazon Basin, southern Africa, and Southeast Asia. An aberration from the seasonal pattern is in the Sahel, which has a relatively high NPPpred throughout both years, except in June and July (not shown).

A large portion of the high NPPpred areas can be attributed to predictability gained by ENSO. These high-predictability areas are concurring with the carbon flux anomalies caused by ENSO-related climate variability . A specific example of this is the disparity in NPPpred between the tropical rainforests of the Amazon and the Congo basins. It shows that the high NPPpred of the tropics is not an intrinsic property of these ecosystems. A reason for the relatively low NPPpred within the Congo Basin could be because it is not strongly impacted by ENSO . These findings highlight the importance of correctly simulating the ENSO process. Especially the localization of ENSO-related rainfall patterns is crucial, since they provide a sustained and predictable anomaly in water availability.

Many of the identified spatial patterns of CFpred can be discovered in similar studies. Most models agree on the Amazon Basin as the global hotspot of CFpred , and some reflect the increased predictability in Southeast Asia and southern Africa , but the comparison of predictability horizons remain difficult due to the use of different predictability metrics.

The results reveal different areas in which an operational NPP forecast can be used to increase food security. The high NPPpred of the Sahel and Kalahari savanna ecosystems (Fig. ) could be used to plan stocking rates in order to avoid grassland degradation due to overgrazing in dry years . Other promising regions are northeast and central Brazil. The high NPPpred in these areas could be used to select crop varieties which are more or less drought tolerant depending on the given forecast.

CFpred is sufficiently captured by the regression models (Eq. ) with a correlation of 0.71 and 0.75 for NPP and Rh, respectively (averaged correlation between the Vc derived from the ensemble simulations and the Vc of the regression model for each grid cell and lead time, not shown). The contributors of CFpred show strong spatiotemporal heterogeneity with drivers alternating across seasons and regions. The temporally averaged contributions to weighted predictability are shown in Fig. . The drivers of NPPpred are SOILpred (sum of midSOILpred and deepSOILpred) and TEMPpred, which explain 62 % and 30 % of the globally averaged NPPpred, respectively. PARpred only contributes 8 % to the NPPpred, most of it in the first month of the simulations. The NPPpred patterns of Vc explained by SOILpred and TEMPpred are similar to the patterns of ACC, although areas with low carbon flux densities are excluded through weighting by absolute flux anomaly. While the NPPpred explained by SOILpred has a spatial extent that broadly covers all regions of high NPPpred, TEMPpred is concentrated in certain areas. TEMPpred is high in a band extending from the Amazon Basin to northern South America, in southern Africa, and in Southeast Asia. The largest contributor to Rhpred is SOCpred (52 %) followed by TEMPpred (27 %). Similar to NPPpred, the temperature component is highest in the Amazon Basin, southern Africa, and Southeast Asia.

In order to facilitate a system for operational NPP prediction, a network of sensors could be installed to gather data on the initial condition of the land surface. The patterns of the role of soil moisture in predicting NPP (Fig. ) reveal the areas on which the efforts in establishing such a network should be focused to maximize the impact.

There are more variables that are regarded as key drivers of NPP variability and could have been regarded as predictors in the regression models. Most importantly, LAI and humidity play an important role in NPP variability . Several studies show the role of a dynamical simulation of LAI in extending the predictability of land surface processes . Here, the inclusion of LAI as a predictor is rejected because of the susceptibility of regression models to correlated predictors. The changing concentration of atmospheric CO2 is causing trends in NPP as global atmospheric levels are rising ; however, we assumed that the interannual variability of CO2 fertilization is below a meaningful contribution to overall variability. Although clay content plays a major role in carbon turnover rates in soil , it is not considered in the JSBACH Rh submodel and was not included in this study.