Model and simulations

The model is the Community Climate System Model version 3 (CCSM3)31 maintained at the National Center for Atmospheric Research (NCAR), with the resolution of T31×’3 and include a dynamic vegetation component and fixed annual cycle of aerosol forcing. As a continuation of the DGL-A simulation of ref. 14, the TRACE experiment is initialized from an equilibrium simulation forced by the LGM forcing (22 kyr ago), and is then forced by the complete set of realistic transient climate forcing, orbital insolation32 (Fig. 1a), atmospheric greenhouse gases33 (Fig. 1d) and meltwater discharge (Fig. 1a); the continental ice sheet is modified according to ICE-5G34, once per 1,000 years for 19–17 kyr ago, and once per 500 years after 17 kyr ago. The coastlines and bathymetry are modified at 13.1 kyr ago with the removal of the Fennoscandian Ice Sheet from the Barents Sea, at 12.9 kyr ago with the opening of the Bering Strait, at 7.6 kyr ago with the opening of Hudson Bay, and finally at 6.2 kyr ago with the opening of the Indonesian Throughflow. Meltwater fluxes largely follow the record of sea level rise and geological indicators of ice sheet retreat and meltwater discharge. The meltwater forcing during mwp-1A consists of contributions from the Antarctic (15 m of equivalent sea-level volume) and Laurentide (5 m of equivalent sea-level volume) Ice Sheets. More details of the TRACE simulation can be found in ref. 35. TRACE reproduces many key features of the response of the climatology in the last 21 kyr as in the reconstruction14,15, such as the AMOC intensity (Fig. 1b, with black and grey lines being two proxies from ref. 36), cross-Equator SST contrast (Fig. 1c), tropical Pacific SST (Fig. 1d).

Four single forcing experiments are integrated in the same way as TRACE, but each is forced by a single transient forcing only with other forcings fixed at conditions at the start of each simulation37. The ORB and CO2 runs are initialized from the TRACE state at 22 kyr ago; ORB is forced by only the transient orbital forcing, and GHG is forced by only the transient greenhouse gas concentrations after 22 kyr ago. The MWF and ICE are initialized at the TRACE state of 19 kyr ago; the MWF is forced by only the transient Northern Hemisphere meltwater fluxes, and ICE is forced by the changing continental ice sheet after 19 kyr ago.

Model ENSO

ENSO simulated by the model for the present day shows many realistic features, although the ENSO period tends to be biased towards quasi-biannual, as opposed to a broader 2–7-year peak in the observation38. The ENSO mode resembles the SST mode29 and propagates westwards as in many CGCMs. In the past 21 kyr, the preferred period of model ENSO remains at quasi-biannual, with the power spectrum changing only modestly with time (Extended Data Fig. 1).

The use of remote precipitation variability to infer the change in ENSO

ENSO’s amplitude is defined normally in terms of the interannual SST variance in the central-eastern equatorial Pacific region, typically the Niño3.4 (170°–120° W, 5° S–5° N) or Niño3 (150–90° W, 5° S–5° N) region. A direct measurement of ENSO’s amplitude can therefore, in principle, be made only using sufficient number of high-resolution proxies of SST variability, such as fossil corals, in this region6. However, because of the insufficient number of direct ENSO proxies, the change in ENSO’s amplitude has been often inferred indirectly from other proxies, notably the interannual variance of certain precipitation-sensitive proxies such as sediment fluxes2,4,7,8 and varve thickness17,39, in regions that are affected by ENSO teleconnection. This indirect inference may be valid under two conditions. (For simplicity, here, we ignore the issue related to the temporal resolution of the proxy.) First, ENSO teleconnections remain stationary throughout time. Second, the proxy site is located in a region under strong ENSO impact; that is, the precipitation variability is highly correlated with ENSO such that most of its interannual variance is indeed caused by ENSO. Outside the region of strong ENSO impact, a significant part of the interannual variance in precipitation is contributed by local variability independently of ENSO40. Nevertheless, the amplitude of precipitation variability can still be correlated with that of ENSO if the local response of interannual precipitation variability to a changing climate forcing, such as the orbital forcing, is similar to that of ENSO, rather than by teleconnection.

CCSM3 reproduces the ENSO teleconnections reasonably well. A comparison of the correlation between the monthly time series of ENSO (Niño3.4 SST) and interannual (1.5–7-yr) variability of precipitation for the present day in TRACE (Extended Data Fig. 4c, 1–0 kyr ago) and the observation (Extended Data Fig. 4d; HadISST and CPC Merged Analysis of Precipitation of 1981–2005) across the globe shows that the model captures the major features of the observed teleconnection, notably the positive correlation extending from the central equatorial Pacific to the South American coast and into the mid-latitude Northern Hemisphere, and the negative correlation surrounding the central-eastern equatorial Pacific, although the magnitude of correlation is somewhat underestimated in the model. In addition, a comparison of the ENSO teleconnection at different periods in TRACE, for example at the LGM (21–20 kyr ago; Extended Data Fig. 4a), early deglaciation (16–15 kyr ago; Extended Data Fig. 4b) and the present (1–0 kyr ago; Extended Data Fig. 4c), shows that the overall features of ENSO teleconnection remain largely unchanged.

In spite of statistically significant ENSO teleconnections globally, the region of strong ENSO impact is confined mainly to the core region of ENSO impact, from the central equatorial Pacific to the South American coast. This core region can be seen as the region with the correlation magnitude above 0.5 in the model (Extended Data Fig. 4a–c). The validity of precipitation variability as a proxy for ENSO amplitude changes in the core region is confirmed by calculation of the interdecadal amplitude correlation between precipitation variability and ENSO. The amplitude is calculated first in a 40-year window from the monthly time series filtered to the band of 1.5–7 years. The local response to slow external forcings, such as orbital and meltwater fluxes, is then filtered by subtracting its 200-year running mean. The high-pass interdecadal amplitude correlation (Extended Data Fig. 4e–h) between the precipitation variance and ENSO variance in the core region of ENSO impact, mainly in the equatorial Pacific to the South American coast, is positive, similar to a previous study26, and highly correlated (more than 0.6) in the central equatorial Pacific of Niño4 and Niño3.4 regions. This suggests that precipitation proxy records in the core region of ENSO impact can indeed be used to infer the change in ENSO amplitude reasonably well. In the very eastern equatorial Pacific and South American coast, such as the Galapagos islands and Ecuador, precipitation variability is also reasonable for inferring ENSO changes, as seen in Extended Data Fig. 3a, b for the Holocene. Nevertheless, in these regions, the teleconnection correlation is not as large as in the central Pacific region (Extended Data Fig. 4a–d) and the interdecadal amplitude correlation is also weak, usually smaller than 0.4 (Extended Data Fig. 4e–h). Some failures of using precipitation variability to infer the correct trend of ENSO amplitude, for example during the early deglaciation in the Galapagos islands, are therefore possible (Extended Data Fig. 3a).

Outside the core region of ENSO impact, the interdecadal amplitude correlation is usually small (Extended Data Fig. 4e–h) and therefore precipitation variability can usually not be used to infer ENSO changes. However, the slow evolution of precipitation variance can still be correlated with that of ENSO. Extended Data Fig. 5a–c shows the correlation of the low-pass (200-year running mean) amplitude between precipitation variability and ENSO for different periods. The most striking feature is the high positive correlation in the central equatorial Pacific and the South American coast, across all the periods, as in the interdecadal amplitude correlation (Extended Data Fig. 4e–h). This is consistent with the implication of strong ENSO impact in this core region, as discussed in Extended Data Fig. 4.

Further issues on model–data comparison of ENSO changes in the Holocene

Our model–data comparison of ENSO amplitude in the Holocene has focused on the qualitative aspects (Fig. 1e). A quantitative model–data comparison would be much more challenging, because of the data interpretation and sample size as well as model deficiencies41. Overall, however, as in other models20, our model underestimates the ENSO change in the Holocene, about 15%, against some reconstruction of SSTs of 50% or higher3,21. However, the small sample size6,21 may not give a robust estimation of the ENSO amplitude trend6. Lake sediments2,4 also show some large changes, but their interpretations remain elusive, especially for a quantitative comparison. ENSO amplitude is sensitive to the different measures such as the number of strongest events and the frequency of occurrence41. Thus, detailed quantitative model–data comparisons should be approached cautiously.

To illustrate the potential uncertainty related to the inherent irregularity of ENSO amplitude16, we use the Monte Carlo method to test the trend of ENSO amplitude in the Holocene derived in the model as in the coral records of ref. 6. A model ‘fossil coral’ record is simulated by a 30-year section of the monthly Niño3.4 SST that is randomly selected between 7 and 0 kyr ago. The ENSO amplitude is calculated as the standard deviation of the monthly SST in the frequency band of 1.5–7 years. The linear trend is then derived using a linear regression of the ENSO amplitudes of a set of 50 corals that are randomly selected between 7 and 0 kyr ago. The probability density function (PDF) of the linear trend is then derived from an ensemble of 10,000 sets of 50-member corals (Extended Data Fig. 6a, the red TRACE pdf profile). The null-hypothesis PDF is derived from an ensemble of 10,000 sets of 50-member pseudo-corals from a SST time series that is derived from the original Niño3.4 SST time series between 7 and 0 kyr ago after a random scrambling in time such that any linear trend is destroyed (Extended Data Fig. 6a, the red Null pdf profiles). It is seen that about half of the trends from the TRACE coral sets are not statistically different from zero at the 95% level. Therefore, consistent with ref. 6, it is difficult to detect a significant positive trend from a set of 50 corals of ∼30 years in length. To detect with high confidence a modest linear trend in ENSO amplitude of about 15%, as in TRACE and other models20, either more or longer corals are needed. If the coral length is maintained at 30 years but the coral members are increased to 200, the linear trend in TRACE can be detected to be significantly different from zero at the 95% level (blue curves in Extended Data Fig. 6a). If the coral members are increased to 1,000, the positive linear trend can be detected at the 99% level (black curves in Extended Data Fig. 6a).

The uncertainty in model–data comparison can also be seen in the evolution of the simulated ENSO amplitude (in the 100-year window, red in Extended Data Fig. 6b) in comparison with the most recent reconstructions from central Pacific corals6 and Peruvian molluscs21, all in reference to their respective late-Holocene ENSO amplitude that is calculated as the average of the most recent millennium (1–0 kyr ago) (Extended Data Fig. 6b). Although both the model and data show an increase in ENSO amplitude from the mid to late Holocene, there are two differences between the model and data: first, the increase in ENSO is less in the model (<20%) than in data (∼50%), and, second, the model does not seem to simulate a mid-Holocene minimum. If the large ENSO intensification and mid-Holocene ENSO minimum are indeed robust features for the real world, the model–data discrepancies would imply substantial model deficiencies. However, these two observational features still remain uncertain, because of the high irregularity of ENSO, the sparse data sampling and data interpretation. For example, a decrease in the window length for ENSO amplitude from 100 years to 30 years in the model (blue line in Extended Data Fig. 6b) to better represent the short length of corals would increase the spread of ENSO amplitude in the Holocene (10–0 kyr ago after detrend) 1.7-fold; the increased spread implies a greater possibility that the small number of coral records could have been influenced by the irregularity of ENSO. Using the spread of the annual range of SST along the Peru coast to infer ENSO amplitude21 should depend on the phase-locking of ENSO with the annual cycle, and could therefore change with time if the phase-locking changes with time as in the simulation (Extended Data Fig. 10). The ensemble spread of the SST reconstructions from δ18O of planktonic Globigerinoides ruber foraminifera in the eastern tropical Pacific5 probably represents the total SST variability (Fig. 1f), which is dominated by the annual cycle variance, rather than ENSO variance (Extended Data Fig. 2b, c). Finally, the ENSO centre may shift between the central Pacific and eastern Pacific21 (Extended Data Fig. 2a), which could also reshape the patterns of ENSO-related precipitation anomalies that often form the basis of palaeo-ENSO reconstructions. Ultimately, high-resolution palaeoclimate data from ENSO centres of action must be expanded significantly to resolve these issues. In particular, we suggest that various types of temperature and precipitation-sensitive proxy records from ENSO’s centre of action—the central equatorial Pacific (Extended Data Fig. 2c, d)—may provide particularly effective benchmarks for model simulations of ENSO variability.

Estimating ocean–atmosphere feedback

To examine the role of ocean–atmosphere feedback in ENSO evolution, we estimate ocean–atmosphere feedbacks in the tropical Pacific in TRACE by analysing the surface ocean heat budget23. We first linearize the SST equation in the mixed layer as where the overbar denotes the annual mean climatology, T is SST anomaly, Q is the total surface heat flux and (u, v, w) are ocean current velocity. By integration above the mixed-layer depth (H 1 ) and then averaging it over a region in the eastern equatorial Pacific, denoted in angle brackets, equation (1) can be approximated as where H(x) is the Heaviside step function; H(x) = 1 if x ≥ 0 and H(x) = 0 if x < 0. Here, all the terms are derived similar to those in ref. 23, except the second term, which represents the mean advection, with the subscripts EB, WB, NB and SB denoting the average along the eastern, western, northern and southern boundaries of the region, respectively, and L x and L y are the longitudinal and latitudinal widths of the region, respectively. The damping coefficients associated with the negative feedback of the surface heat flux and mean advection are derived as the regression coefficients with SST as

The atmospheric response sensitivity to the eastern Pacific SST is estimated approximately in the regression coefficient μ a between the cross-basin mean atmospheric wind (stress, [τ x ]) and the eastern Pacific SST as The entrainment temperature is proportional to the depth of the local thermocline as Finally, the oceanic response sensitivities to the wind stress are regressed as for the thermocline slope, upwelling and zonal current, respectively. Here, is the thermocline depth in the western equatorial Pacific. With all the regression coefficients in equations (3–6), equation (2) can be approximated as where the total feedback parameter, or the BJ index, is

The BJ index consists of five feedbacks terms, which are, in order, the surface heat flux feedback, the mean advection feedback ( ), the zonal advection feedback, the local upwelling feedback, and the thermocline feedback. The last three feedbacks are all proportional to the atmospheric response sensitivity (μ a ), and each is further proportional to its own oceanic response sensitivities (β). Here, we choose H 1 as 50 m, w and as the anomalous and climatological upwelling at 50 m, h approximately as the heat content anomaly, which is derived as the column-weighted temperatures at the three model levels of 4 m (surface), 56 m and 149 m, and as the difference in climatological temperatures between the surface and 100 m. All the climatology variables are derived as the time-mean over a sliding window of 100 (or 300) years, and the anomalies are the monthly deviations from the climatological seasonal cycle.

For the eastern part of the equatorial Pacific (180–80° W, 5° S–5° N), which is the region of dominant ENSO variability (Extended Data Fig. 2a), the BJ index is negative, mainly as a result of the mean (meridional) advection feedback (Extended Data Fig. 7b). The negative BJ index indicates that ENSO is a stable mode maintained by stochastic forcing in CCSM3, as in most CGCMs42. Almost all the feedbacks tend to follow the orbital forcing in the southern subtropics (Fig. 2), with the magnitude of the feedback decreasing towards the early Holocene, but increasing towards both the late Holocene and the LGM. There is also significant millennial variability reminiscent of the meltwater forcing during the early deglaciation, especially in the upwelling feedback. The dominant role of orbital forcing for the slow evolution throughout the 21 kyr is also confirmed by the similar BJ indices in TRACE and ORB runs (Fig. 2d), and the dominant role of the upwelling feedback in TRACE (Extended Data Fig. 7b) and ORB (not shown). Finally, the mean advection feedback also shows an abrupt increase (less negative) at ∼14 kyr ago due to the retreat of the ice sheet, a point that is returned to below.

The BJ index is consistent with the ENSO amplitude over most of the Holocene, both increasing from 8 kyr ago towards the late Holocene (Fig. 2b, d, or Extended Data Fig. 7a). Therefore, ENSO intensification in the Holocene can be interpreted from the linear instability perspective as being caused by increased ocean–atmosphere feedback. The increase in the BJ index is dominated by the upwelling feedback, with a minor contribution from the thermocline feedback; their sum overwhelms the decrease (more negative) in the two negative feedbacks (Extended Data Fig. 7b), leading to a modest increase in the total feedback and, in turn, the ENSO amplitude (Extended Data Fig. 7a). The increases in the three positive feedbacks are contributed by a common atmospheric response sensitivity (μ a ; Extended Data Fig. 8a) as well as by their respective oceanic response sensitivities (β) (Extended Data Fig. 8b, c, d).

In more detail, the upwelling feedback is further enhanced significantly by the intensified stratification (Extended Data Fig. 8f), which is caused by the precessional forcing of the subtropical South Pacific12. The weaker stratification in the early Holocene is caused by the precessional forcing (Extended Data Fig. 9a) on the subtropical South Pacific, where the increased insolation in austral winter warms the surface water in winter (Extended Data Fig. 9b) and then the subsurface thermocline all year round through late winter subduction (Extended Data Fig. 9c); the warmer subduction water is eventually transported into the equatorial thermocline, warming the subsurface and decreasing the stratification (Extended Data Fig. 9d). Our further calculations with various domain choices for the eastern Pacific show that the dominant contribution of the upwelling feedback is robust. The small zonal advection feedback in Extended Data Fig. 7b is caused partly by a small climatological SST zonal gradient averaged across the region—that is, —which is proportional to the small difference of climatological SST between the eastern and western boundaries of the eastern Pacific domain chosen here (180° W versus 80° W). With other choices of the domain, such as the Niño3.4 domain (170° W versus 120° W), the increase in the zonal advection feedback in the Holocene is larger, but still smaller than that of the upwelling feedback.

In contrast to the Holocene, during the deglacial period (∼18–8 kyr ago), the BJ index does not covary with the ENSO amplitude for millennial variability, for example around the periods of HS1 and YD. The millennial modulation of ENSO therefore cannot be attributed to the change in feedbacks. The millennial modulation of ENSO varies out of phase with the seasonal cycle and therefore can be attributed to the interaction with the seasonal cycle through the nonlinear mechanism of frequency entrainment27, with the equatorial seasonal cycle altered by the meltwater water discharge through the AMOC26. The response sensitivities, the climatological states and in turn the three positive feedbacks (Extended Data Fig. 7b) all evolve in more complex patterns during the deglacial than in the Holocene. The negative feedback in heat flux shows only modest changes. The most striking change is an abrupt decrease (less negative) in the mean advection damping at ∼14 kyr ago (Extended Data Fig. 7b), which is contributed mainly by the mean zonal advection. This abrupt weakening of the mean (zonal) advection damping is caused by the large retreat of ice sheet at 14 kyr ago, and is consistent with the abrupt increase of ENSO amplitude (Fig. 3a) and mean (zonal) advection feedback (similar to that in Extended Data Fig. 7b) in the ICE run at ∼14 kyr ago. The abrupt intensification of ENSO at ∼14 kyr ago in ICE is caused by frequency entrainment through the sudden decrease in the annual cycle (Fig. 3b). The decreased annual cycle is associated with an annual mean SST in the eastern Pacific that is more symmetrical about the Equator, which is forced by the atmospheric teleconnection response to the large retreat of the North America ice sheet at ∼14 kyr ago. The retreat of the ice sheet induces a northward migration of the atmospheric westerly jet over the North Atlantic, an increase in surface easterly in the tropical North Atlantic and in turn the tropical eastern Pacific; the retreat of the ice sheet also changes the atmospheric stationary wave response, which leads to a cooling and an expansion of sea ice over the subpolar North Pacific, and also an intensified trade wind in the eastern Pacific. Either way, the intensified trade wind in the eastern Pacific propagates equatorwards through ocean–atmosphere coupling, leading to a cooling north of the Equator, which decreases the SST gradient northwards and leads to an annual mean SST that is more symmetrical about the Equator in the eastern Pacific. The detailed mechanism of the ENSO response in ICE is beyond the scope of this study and will be presented elsewhere.