Introduction

The major agencies tracking global surface temperature anomalies (GSTA) rank 2022 as the 5–6th warmest on record1,2,3. That global warming continues is clear4, and apparent in the markedly strengthening impacts felt around the world5. Satellites and ocean data also document a strengthening uptake of energy in the Earth system, related to an increasing imbalance between incoming solar radiation and energy re-emitted to space6,7. The recent rate of global mean surface warming—a crucial measure for tracking the progress of climate change and the effects of future mitigation efforts—is however less clear8,9. Primarily, this is due to the influence of internal variability on year-to-year temperature anomalies. 2022 saw strong, prevailing La Nina conditions in the Pacific, which is known to cool the surface, globally, by up to several tenths of a degree Celsius on annual mean. The same was true for 2021, and parts of 2020; an uncommonly long period of cool conditions in the Pacific. This leads to an expectation of observed GSTA values below the full anthropogenic warming since 1850–1900, and an apparent short-term slowdown in the rate of surface warming.

Concurrently, the rate of change, and balance between components of, anthropogenic radiative forcing is also changing4. Atmospheric concentrations of CH4 have increased strongly in the recent decade, while the increase in anthropogenic CO2 emissions, the primary driver of warming, has slowed to ~1%/year, relative to ~3%/year in the period 1990–201010. Emissions of SO2, precursor of cooling sulfate aerosols, have decreased strongly over the last decade, largely due to strong Chinese efforts to combat air pollution11. Because of the rapid and potentially non-linear influence of aerosol emission changes on surface temperatures8, and the remaining uncertainty on the total anthropogenic aerosol forcing of the climate12, the near-term GSTA evolution can provide a crucial test of the strength of the aerosol-climate interaction. Tracking the rate of change of global surface temperatures is therefore crucial, on both short and long time scales.

Recently, we published a method for filtering out parts of the influence of sea-surface temperature (SST) patterns on the observed global mean surface temperature anomaly13. Briefly, a model-based transfer function is used to relate an SST fluctuation in one location to a global mean effect. This function is in turn applied to the realized, detrended SST pattern for a given month or year, to arrive at a total influence on the GSTA from all ocean areas, which can subsequently be filtered out (Methods). This reduction of the influence of internal variability is an advantage over simple running means, since it includes a physical mechanism linking the SSTs to the GSTA. It is also distinct from common multi-regression approaches that primarily use an ENSO index to quantify ocean variability14, and from formal detection and attribution techniques as it does not rely on forcing estimates and dedicated simulations.

Applying the method to the HadCRUT5 data series, we found that for the (then) last 50 years (1971–2020), global warming had progressed at an overall rate of 0.19 °C/decade13. Here, we update this analysis to include the La Nina influenced years of 2021 and 2022, and show how internal variability has recently affected seasonal and annual global mean temperatures. We then use the method to revisit observed and modelled changes in the rate of global mean surface warming over the last 50-, 20- and 10-year periods.

Results

50-year warming rates

In Fig. 1, we present a breakdown of the SST influence on the GSTA in HadCRUT5, from 1850 and through the last calendar year, including an in-depth look at the last 10 years. The warming influence of the 2016 El Niño is clearly visible, as is the La Niña influence on 2021 and 2022. The annual mean SST related influence on 2021, in our method was found to be −0.09 °C. 2022 was also influenced by the La Nina conditions, but to a lesser degree; we find a cooling of −0.04 °C. For comparison, the El Nino influence in 2016 was +0.16 °C. In all, this places 2022 directly on the latest 50-year (1973–2022) trend, which remains at 0.19 ± 0.01 °C/decade. The error is the 5–95% confidence interval of the 50-year regression, using the HadCRUT5 ensemble mean.

Fig. 1: Steady course for global surface warming for 50 years.
figure 1

All panels show global, annual mean surface temperature anomalies from the HadCRUT5 data series, raw (red) and SST influence filtered via a model derived transfer function (black). The upper and lower insets show, respectively, the full data series since 1850, and the latest 10 years. Anomalies are taken relative to 1850–1899.

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We also performed the same analysis for three other gridded surface air temperature data products. For the GISTEMP v4, NOAA v5.1 and Berkeley Earth (BEST) surface temperature, we find 50-year warming rates of 0.19, 0.18 and 0.17 °C/decade, respectively. See Table 1. The mean, filtered warming rate of the four series is 0.18 ± 0.01 °C/decade. For recent individual years, all four series give similar results after filtering (see Supplementary Methods 1 and Supplementary Figs. 13).

Table 1 Global mean surface warming rates for the recent 50-, 20- and 10-year periods, and rate changes calculated using 20-year intervals.
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An interesting feature of the filtering method is that it allows us to extract the pattern of ocean temperature influence on the GSTA through a given year. Firstly, we note that the detrended seasonal surface temperature anomalies from HadCRUT5 capture a range of weather events known from news reports of extreme conditions (Supplementary Fig. 4). 2021 began with a cold spell over northern Eurasia, driven by a collapse of the polar vortex, while SSTs are dominated by a very cold Central and Eastern Pacific. This had a strong cooling influence on global surface temperatures in Spring of 2021, albeit counteracted somewhat by a warm fluctuation in the Western Pacific. For 2022, the well documented spring and summer heatwaves in Europe and Asia are apparent, as is a Pacific La Nina pattern that persists through the year. However, other ocean regions had concurrent warm conditions, notably the North Pacific and the Southern Ocean, which counteracted some of the Pacific cooling. An ocean surface hot spot in the Southern Atlantic also contributed to a warmer GSTA toward the end of 2022.

Broadly, we find that anthropogenic global warming is still on a steady course, with recent years tracking near the expectation from the linear 50-year rate (Fig. 1). However, there have been recent discussions, both in the scientific literature14,15 and in the public debate, about the possibility of a higher recent rate-of-change of global surface temperature. The increase in Ocean Heat Content (OHC) is also likely to have been accelerating over the last 50 years16,17, which raises the question of whether this change is also reflected in GSTA values.

Warming rate increases since 1990

Table 1 shows warming rates also for the most recent 20- and 10-year periods. After filtering, these are indeed consistently higher than the 50-year average, consistent with recent literature4. In Fig. 2, we investigate this further using filtered data series, updated through 2022, and perform a comparison to CMIP6. Panel a shows filtered GSTA values for the four major data series, with a common, recent baseline (1973–2022). For HadCRUT5, we also show 20-year linear fits at the start and end of the 50-year period. Panel b shows how the regression coefficient of the 20-year fits (in °C/decade) changes with time, for unfiltered and filtered data. Both show an overall increase, as previously documented15, but the filtered data have a markedly stronger signal-to-noise ratio, of about 1, compared to 0.5 for unfiltered data. A linear regression gives a warming rate increase of 0.012 °C/decade/decade, with a 5–95% confidence interval of [0.008, 0.017]. We also note that the time evolution, with a step-up in rates after 1990, is qualitatively similar to what is found when performing a similar, 20-year sliding window trend analysis on NOAA Ocean Heat Content observations (Supplementary Fig 5).

Fig. 2: The rate of global surface warming has been elevated since around 1990.
figure 2

a Filtered global surface temperature anomalies for four data series, relative to a common baseline. Dashed lines show 20-year linear regressions for HadCRUT5. b Time evolution of rate-of-change of 20-year regressions for HadCRUT5. Open circles show unfiltered data, closed circles show filtered data. The dotted line shows the 50-year warming rate, the yellow box shows the 5–95% confidence interval of the 50-year regression. The dashed line is a linear regression, showing the increase in warming rate over the 50-year period. c Warming rate increase (the regression coefficient from the fit in b), as function of the length of the fit window, for HadCRUT5. The dotted line shows the 20-year window from b. Error bars are 5–95% confidence intervals from the regression. Open circles and dashed lines (offset for clarity) show unfiltered data. d 50-year filtered warming rates (y-axis) vs the increase in rate over this period, for four data series (colored circles) and 119 CMIP6 simulations (dots). For CMIP6, the colors indicate the Equilibrium Climate Sensitivity (ECS). Diamonds and triangles show members from three Large Ensembles (CanESM5, ACCESS-ESM1–5, MPI-ESM1-2-LR).

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We now redo this analysis for window lengths of 10–30 years, to see if there is any dependence of the rate increase on the chosen window. Panel c shows the resulting regression coefficients. For all trend windows longer than about 20 years, we find a consistent rate increase for the filtered data. The 5–95% confidence intervals (error bars) also decrease markedly with the length of the fit window, and is strongly reduced by the filtering procedure. The raw data also show an increasing warming rate, but with greater uncertainty and with stronger influence of annual-to-decadal scale internal variability. We also note that the raw data consistently shows a stronger rate increase than the filtered data, indicating differences in the amount of warming filtered through the time period. While the reasons for this require further investigation, it may be due to a systematic shift in SST patterns over the period of study.

Again, similar results are found for the other data series, albeit with different values for rate increases. The GISTEMP, NOAA and BEST surface temperature series yield filtered (20-year window) warming rate increases of 0.022, 0.023 and 0.008 °C/decade/decade, respectively. The mean, filtered warming rate increase of the four series is 0.016 °C/decade/decade. See Table 1, which also shows confidence intervals and unfiltered values. We note that, after filtering, the observational data series are fully consistent in their 50-year warming rates, but inconsistent in their rate increases. This is possibly due to differences in treatment of areas with low observational density, or to differences in their SST data series which map onto the corrections applied by our transfer function.

While we do find a consistent increase in warming rate over the last 50 years, we find no evidence of an “acceleration” of global surface warming in recent years, in the sense of a continuous rate increase. Rather, the strongest increase in rates seems to have occurred as a step-up around the middle of the 50-year period, with a levelling off in later years. This is similar to what is found for OHC (Supplementary Fig 5).

Comparisons to CMIP6

Expectations for near-term warming trends typically come from modelling exercises like CMIP6, using a set of pathways for future emissions and greenhouse gas concentrations. To evaluate any changes in trend, it is therefore of relevance to know if the current model ensemble captures the observed evolution. In Fig. 2 panel d, we compare the 50-year warming rates and rate increases to those from an ensemble of 119 Earth System Model simulations, provided as part of CMIP6 and using historical emissions until 2014, and a Shared Socioeconomic Pathway (SSP5–8.5) thereafter. Note that the results are insensitive to the choice of a high or low emission pathway (SSP5–8.5 or SSP1–2.6), as we only extend to 2022 where emissions only differ moderately between SSPs. All simulations have been filtered using the transfer function, as for the observations. We show one ensemble member per model, except for three selected models (CanESM5, MPI-ESM1-2-LR and ACCESS-ESM1-5) where we include multiple members to provide an indication of the effects of internal variability. Firstly, virtually all CMIP6 simulations have higher 50-year warming rates than the observations. This result has been discussed in previous literature and is likely due to a combination of high equilibrium climate sensitivities in some CMIP6 models18, and that the realized SST patterns are not well captured by the model ensemble, notably in the Pacific19,20. We also find a tendency for more rapidly warming models to have a higher rate change over the 50-year period (Fig. 2). These models are generally characterized by higher Equilibrium Climate Sensitivities (ECS) and Transient Climate Responses (TCR; see Supplementary Methods 2 and Supplementary Fig 6). This is particularly clear for the three large ensembles included, which come from models with ECS values ranging from 3.0 °C to 5.6 °C. The observations are notable in that they have higher rate changes than all models of comparable mean warming rates, and generally lie at the upper end of the CMIP6 mean rate change (0.007 °C/decade/decade, calculated using one ensemble member per model). Hence, when looking at warming rate and rate increase in combination, the observations sit well outside the CMIP6 model ensemble. Identifying possible reasons for this requires a broader analysis with other tools than used here, but they may include the poor representation of Pacific SSTs19, influences of aerosol forcing21, and/or the broader climate response to the 1991 eruption of Mt. Pinatubo22.

Discussion

Returning to the near-term evolution of global mean surface temperatures, tracking the global and seasonal evolution of the GSTA for the coming years will clearly give important information on the condition and evolution of the climate system. Firstly, El Nino conditions are projected to develop in late 2023, and last well into 2024. While the strength of the El Nino event is not yet known, when combined with the ongoing rates of change, it can be expected to yield record high GSTA values in 2024. In addition, however, there are still crucial uncertainties remaining about the response of the climate system to continued anthropogenic forcing. One key question is the historical balance between warming from greenhouse gases, notably CO2 and methane, and cooling from aerosols, notably sulfate23. While there is a wide spread in possible future aerosol emissions in the Shared Socioeconomic Pathways generally used by the climate modelling community24, most scenarios in which emissions are reduced in line with the aims of the Paris Agreement also include strong reductions in aerosol emissions25. The possibility of a very strong aerosol radiative forcing has still not been ruled out. If this is the case, the warming effects aerosol mitigation could rapidly manifest in a change in the rate of global warming.

We therefore advocate for additional attention to, and efforts in tracking, the evolution of the global surface temperature anomaly, when filtered for influence of internal variability. Our conclusion is that global warming continued at a steady rate through 2022, consistent with both longer term 50-year warming rates, and more recent, higher rates. Also, CMIP6 models generally do not reproduce the observed combination of mean warming rates since 1973, and the recent rate increases, which is concerning for impact studies and climate risk assessments based on these ensembles of simulations. We caution, however, that our conclusions are based on a tool from one model only (Methods), and only take into account sea-surface temperature fluctuations. More sophisticated analyses are possible, using multiple models and also taking into account a wider range of factors such as stratospheric temperatures, volcanic eruptions and the heterogeneous pattern of anthropogenic aerosol emissions, to provide both the scientific community and policy makers with accurate information on the evolution of climate risks over the coming years and decades.

Methods

Datasets

The primary dataset used in this study is the HadCRUT5 gridded dataset of global historical surface temperature anomalies, version 5.0.1.01. We used monthly data for the period January 1850–December 2022.

We also used three other gridded surface temperature data products, on monthly resolution, from their start dates and through December 2022: The GISS Surface Temperature Analysis version 4 (GISTEMP v4)2,26, NOAA Global Surface Temperature Dataset (NOAAGlobalTemp) Version 5.1 (updated July 2023), and Berkeley Earth (April 2023 update)27.

Trend removal

The pattern of monthly internal temperature variability is isolated from the long-term influence of anthropogenic warming via a boxcar smoothing with a 10-year window, applied at each grid point of the input dataset, relative to a 1850–1900 baseline. This removes the underlying global mean temperature increase, geographical patterns of global warming, and any seasonal differences. Near the endpoints, where there is insufficient data for the 10-year mean, we ensure consistent weighting by mirroring the data points. This was shown in Samset et al. 202213 to have a negligible impact on the overall results, including trend estimates, even for the end years of the series. Note, however, that our chosen method will not remove decadal scale variability in regional temperature patterns.

Green’s functions

The analysis performed is identical to that documented and used in Samset et al. 202213, see that publication for a more thorough writeup and various sensitivity tests and consistency checks. Briefly, we use a Green’s Function (GF) calculated with the CESM1.2.1-CAM5.3 Earth System Model, monthly resolved and taking 40-year simulations with fixed sea-surface temperatures as input28,29. A GF, in our usage, relates an idealized increase in sea-surface temperature at a given location, to resulting influences on radiation, clouds, water vapor and, ultimately, global mean surface temperature, and allows us to calculate the modulation of global mean surface temperatures resulting from a given pattern of SST variability. It is based on simulations where the SST was individually perturbed in 74 (partially overlapping) ocean patches of 80° longitude and 40° latitude. We use 2-meter surface air temperature to quantify the modulations.

GSTA modulations are calculated by multiplying the Green’s Function for that month with the detrended SST pattern from HadCRUT5. The total modulation is the sum of the contributions from all ocean-dominated grid points. For this calculation, monthly temperature fields from HadCRUT5 and GISTEMP have been regridded to the GF resolution (2.5° latitude, 1.9° longitude).

Climate model data analysis

Climate model simulations shown in Fig. 2 were analyzed identically to the surface data series, including filtering using the Green’s Function. All simulations used were provided for the ScenarioMIP30 CMIP6 Endorsed MIP31, and made available to the community through the Earth System Grid Federation (ESGF). We made use of 250-year transient simulations using the CMIP6 historical (1850–2014) and Shared Socioeconomic Pathway (SSP) (2015–2100) emission datasets. Two SSPs were used (SSP1–2.6, SSP5–8.5), to extend the historical data through 2027. (The main analysis runs through 2022, but we use subsequent data so as to avoid the need for mirroring the endpoints). The results of Fig. 2 are insensitive to the choice of SSP (SSP5–8.5, SSP3–7.0, SSP2–4.5, SSP1–2.6). Only monthly mean temperature data (Global Surface Air Temperature at 2 meters) was used. See Supplementary Methods 1 for a list of the 33 individual models and 119 ensemble members used.