Many changes have occurred over the historical period, 1850–2014: the industrial revolution, during which North America and Europe in particular emitted increasing amounts of greenhouse gases, aerosols, and aerosol precursors; the introduction of clean air acts by North America and Europe starting in the 1950s that led to reduced aerosol emissions from those regions; the industrialization of China and India leading to increased emissions of greenhouse gases and aerosols; and the general continued rise in the rate of global greenhouse gas emissions. Climate change over the North Atlantic (NA) on decadal and longer timescales is influenced by many different factors, with the most significant likely being greenhouse gas forcing, aerosol forcing, mid-latitude cloud feedbacks mediated by temperature changes, natural variability and the Atlantic Meridional Overturning Circulation (AMOC). Many of the processes involve changes in the upwelling short-wave (SW) radiative flux at the top of the atmosphere (FSW↑); therefore, FSW↑ is a key property of the Earth system when considering climate variability.

Fairly long-term observational records of FSW↑ exist for the recent part of the historical period e.g. 1985–2019; that may be useful for evaluating models and attributing changes in climate to various causes. However, to understand what model evaluation using such long-term datasets is telling us about the causes of regional climate change, it is necessary to understand the driving factors of long-term changes in FSW↑. In this study we use the UK Met Office climate models to better understand the underlying processes and what the observed long-term trends in FSW↑ might be telling us about model performance and causes of regional climate change.

We focus on the NA region, because it plays a major role in several aspects of the Earth system. The NA ocean sequesters large amounts of carbon and heat from the atmosphere and therefore helps to regulate the global climate . Processes in the NA are thought to help determine the speed of the AMOC , which transports a significant amount of heat northwards, representing ∼ 25 % of the total (atmospheric plus oceanic) global northward heat transport at 24–26∘ N . The AMOC transports a large amount of energy from the Southern Hemisphere to the Northern Hemisphere, something that is not true for the equivalent circulations in the Pacific . This cross-equatorial oceanic heat flow is important, because it leads to a compensating southward cross-Equator heat flow within the atmosphere, and this in turn causes the Intertropical Convergence Zone (ITCZ) to be positioned north of the Equator. Changes in the AMOC can therefore lead to changes in the ITCZ position, which could bring great disruption to the climate of not only the Atlantic region but also the climates of the global tropics, subtropics and potentially the midlatitudes via changes in precipitation and changes to the Indian and Asian monsoons .

The NA is surrounded by North and Central America, Europe, and North Africa, which are large regions of high population density. This means that (1) there is a great deal of influence from short-lived anthropogenic species such as aerosols over the NA and (2) that changes in the NA climate system can have large impacts on human society. Sea surface temperature (SST) variability in the NA has been associated with impacts on important phenomena such as tropical storm and hurricane activity ; anomalies in rainfall in Europe and North America ; African Sahel and Amazonian droughts ; Greenland ice-sheet melt rates ; sea-level anomalies ; and the strength of the mid-latitude jet . provides a review of changes in the North Atlantic climate system, with a focus on more recent changes.

Aerosol effective radiative forcing (ΔFaereff) is a key driver of long-term changes in FSW↑ over the NA and globally. For the calculation of ΔFaereff, all physical variables are allowed to respond to perturbations except for those concerning the ocean and sea ice, e.g. see, meaning that surface temperatures need to be constant. As discussed further below, this makes ΔFaereff difficult to calculate using time series from observations or coupled climate models since radiative fluxes respond to changes in temperature, for example, due to cloud feedbacks. FSW↑ is a focus for aerosol forcing, because aerosol forcing generally occurs through the effect of aerosols on short-wave radiative fluxes rather than long-wave fluxes; for example, estimate a global SW ΔFaereff of -1.26 W m-2 and a long-wave ΔFaereff of 0.17 W m-2 for UKESM1 (UK Earth System Model v1). Henceforth in this paper, we only consider short-wave fluxes, forcings and feedbacks.

ΔFaereff can be separated into a component due to aerosol–radiation interaction (ARI) that occurs in cloud-free air (ΔFarieff; sometimes also known as the direct effect) and a component due to aerosol–cloud interaction (ACI, or indirect effects), designated as ΔFacieff. The ACI component of ΔFaereff can also be broken down into two further components. First is that due to a change in cloud droplet concentration (Nd) at constant liquid water content (LWC) and constant cloud fraction (fc), which causes a change in the cloud droplet effective radius (re) and hence cloud albedo. Here we will designate this component ΔFaciNdeff, often termed the instantaneous radiative forcing or the Twomey effect . Second is that due to rapid adjustments of LWC (or the vertical integral of this, which is the liquid water path (LWP), L) and/or adjustments in fc that occur in response to the initial decrease in droplet size associated with the Nd increase. Note here that we define L to be the in-cloud value not the mean of a partly cloudy sky. We designate the forcings from these adjustments as ΔFaciLeff and ΔFacifceff and note that ΔFacieff ≈ΔFaciNdeff + ΔFaciLeff + ΔFacifceff. The mechanisms that cause these adjustments involve several microphysical and thermodynamical processes . For regions of the NA north of 18∘ N, UKESM1 suggests that ΔFacieff greatly dominates over ΔFarieff . Decomposing ΔFacieff further, found that ΔFaciNdeff and ΔFaciLeff dominate the ΔFacieff forcing in the northern regions of the NA (north of around 40∘ N), whereas ΔFacifceff dominates further south.

Models show that aerosol forcing has influenced the climate variability of the NA. showed that surface aerosol radiative forcing was the dominant driver of decadal changes in sea surface temperatures (SSTs) for the atmosphere–ocean coupled global circulation model (the UK Met Office HadGEM2-ES model) that was used in the Fifth Coupled Model Intercomparison Project (CMIP5). showed that for the CMIP6 models aerosols acted to speed up the AMOC during the historical period, whereas greenhouse gases slowed it down. Climate models also predict that during the 21st century a region in the northern NA will experience less warming under the influence of greenhouse gases than the rest of the globe (termed the NA “warming hole”), related to the slowing down of the AMOC . Over the historical period, aerosols have likely delayed the formation of this warming hole by speeding up the AMOC .

Despite its importance, aerosol forcing remains the most uncertain of the forcings. It would be desirable to be able to use long-term trends in observable quantities like FSW↑ to determine aerosol forcing from the observations in order to constrain models. Long-term records of FSW↑ e.g. the DEEP-C dataset for 1985–2019; have the potential to evaluate some aspects of model performance in terms of aerosol forcing. However, in order to understand what model evaluation using such a dataset is telling us about model performance, it is necessary to understand what has been driving long-term changes in FSW↑.

There has been some previous work towards using long time records to estimate aerosol forcing and evaluate models, although the feasibility of this approach remains in question. used observations of surface SW flux from the GEBA (Global Energy Balance Archive) network over Europe for the period 1990–2005 to attempt a constraint on the global aerosol forcings predicted by the CMIP5 climate models. At the locations of the GEBA stations, the effective global aerosol forcings across the different models correlated with the change in surface SW model flux. The observations of the latter were then used to infer the most realistic range of effective global aerosol forcing. A potential issue with this approach is that it relies on the accuracy of the relationship between the two variables across the different models. For example, the relationship is likely affected by the balance of forcings and feedbacks within the different models, which are highly uncertain and may vary depending on the time period chosen. used satellite observations to infer the total instantaneous global radiative forcing of the climate for the 2003–2018 period. This included the effect of greenhouse gases and a variety of other forcings, but for aerosol forcing only the ARI component was included and not ACI. Using MODIS time series from 2003 to 2017 for oceanic regions of the NA (off the east coast of the US and the west coast of Portugal) and off the east coast of China, found no relationship between long-term changes in aerosol and changes in LWP, which may indicate a forcing from aerosols via cloud adjustments that is too small to be identified over the relatively short time period given the large inter-annual variability in LWP.

One of the main complications with using long-term records to estimate aerosol forcing is that there are several other drivers of changes in clouds over long timescales that we attempt to characterize in this study. One such driver is climate change, i.e. changes in temperature and sea-ice cover, which causes cloud–climate feedbacks. For example, over recent decades, warming due to greenhouse gas emissions has increased rapidly, but aerosol emission rates have also varied over the historical record which will affect temperatures too. The resulting changes in clouds from cloud–climate feedbacks must be taken into consideration when attempting to estimate aerosol forcing using long-term records.

Cloud–climate feedbacks are very important in the NA region. showed using satellite observations that cloud fraction has changed substantially between 1983 and 2009 and that these changes are well predicted by models. The cloud feedback operating in this region is thought to be the mid-latitude cloud feedback, whereby warming can cause an expansion of the Hadley cell and a poleward shift of the storm tracks that can reduce mid-latitude cloudiness , leading to an increase in short-wave radiation reaching the surface. This amplifies the temperature change and hence is a positive feedback. Satellite observations have been used to evaluate global model cloud feedbacks, but this approach may lead to an estimate of cloud feedback that is too negative due to the specific pattern of SSTs that occurred over this period, namely a cooling over subtropical stratocumulus regions despite the overall global warming. This caused a local increase in cloud coverage over subtropical stratocumulus regions that acted to increase FSW↑, thus making the cloud feedback more negative. Care is therefore needed when using observations to infer cloud feedbacks.

In this study we use the UK Met Office climate models to better understand the underlying processes and what the observed trends in FSW↑ are telling us about model performance and the causes of climate change over the NA. There has been some work with related aims before. For example, showed that, across the CMIP6 models, mean cloud feedback strength and an estimate of mean aerosol forcing were negatively correlated over the 1950–2000 period such that models with a stronger negative aerosol forcing tended to have a more positive cloud feedback. This was particularly true for models that were more consistent with the observed historical temperature change. For those models, the equilibrium climate sensitivity was also negatively correlated with the aerosol forcing. These results suggest some degree of model tuning between aerosol forcing (causing a cooling) and cloud feedback (causing a warming) to allow for the recreation of observed temperatures. Changes in radiative flux relative to preindustrial times for the 1950–2000 period in the models with the strongest cloud feedback parameters were caused almost entirely by aerosol forcing rather than temperature-induced feedbacks; the models with small cloud feedback parameters showed very little change in radiative flux for this period.

We go further than the above work since we focus on simulations from one modelling centre and break down the underlying causes of the long-term short-wave radiative changes in that model in terms of clear-sky effects, cloud variables and emission types. We separate the aerosol forcing and cloud–climate feedback effects on short-wave radiative changes using different techniques to those used previously in order to more precisely estimate the aerosol forcing. Finally we also use the results to draw conclusions about the feasibility of using long-term observations to quantify aerosol forcing and to evaluate model performance, and we compare our model results to long-term observations.

We now compare the modelled time series with observations. Reliable observations are only available in the later parts of the time series. For FSW↑, we use the DEEP-C dataset that is available from 1985–2014; for Nd we use MODIS data from 2003–2012 (see Sect.  for details); for τa we use 2003–2012 Level-3 MODIS Aqua monthly mean data from the combined 550 nm Dark Target and Deep Blue product “Dark_Target_Deep_Blue_Optical_Depth_550_Combined” ; for fc we use PATMOSx and ISCCP data from for 1983–2009; for Lall-sky we use the MAC-LWP (Multi-Sensor Advanced Climatology of Liquid Water Path) microwave satellite instrument dataset for 1988–2014 (L is not available from this instrument); and for surface temperature we use the data from the UKESM1 atmosphere-only model run that uses observed SSTs from 1985 to 2014 (chosen to coincide with the FSW↑ observations).

Figure  shows the same time series as in Fig.  but with the observations added and with the trends shown for the period of the relevant observations. Figure  shows the modelled and observed trends for the two time periods along with uncertainties. It shows both the range of trends across the model ensembles and the trend from the ensemble mean (along with its uncertainty). It is clear that the modelled FSW↑ values are too high over the 1985–2014 time period and that the ensemble mean trends are too steep. There is a reasonable amount of spread across the model ensembles, but all of the ensemble members have a stronger trend than the DEEP-C data. However, the trends from some members are within the uncertainty of the observations. The results indicate that most ensemble members have a FSW↑ trend that is too steep, resulting in a ΔFSW↑ that is too high.

Modelled Nd trends and absolute values for UKESM1 are very close to those observed, although the time period is quite short and the uncertainties are large. We also note that the time-mean Nd in this model tends to be underestimated in the north of the Atlantic and overestimated in the south ; hence, the good agreement may disguise some compensating biases. The HadGEM model slightly underestimates the absolute values and trend, suggesting that the larger aerosol forcing seen in UKESM1 and the larger-magnitude ΔNd values pre- and post-1970 may be more realistic.

The absolute values of τa match the observations (MODIS Aqua) well for UKESM1, but τa is overestimated by HadGEM. Since Nd was slightly underestimated by HadGEM, this demonstrates that τa is not always a good proxy for Nd. Similar reasoning may explain why there is a fairly small trend in τa from the observations but a fairly large trend in the observed Nd. The UKESM1 trend is slightly larger in magnitude than that from the observations, and the trend from HadGEM is larger still. However, there is considerable uncertainty in the observed trend and considerable spread in the trends across the ensemble members such that it is difficult to conclude that the model τa trends are too large.

For fc, the observations are not useful to evaluate the absolute magnitude since they are only provided as anomalies, but they are useful for looking at trends. The modelled trends match the ISCCP trend well but slightly overestimate the magnitude of the PATMOSx trend. However, the observation time series is very noisy and the trends are uncertain. There is also a wide spread of model trends across the ensembles showing that cloud fraction trends over these lengths of time are highly variable such that some of the ensemble members agree with both sets of observations. This makes it difficult to evaluate the model against reality; only one realization out of a range of possibilities will have occurred in the real world. Since it was shown earlier that changes in fc are the main driver of the changes in FSW↑ in the post 1970 period (Fig. ), the expectation is that the model mean fc trends would be too steep in order to produce the FSW↑ trends that were too steep. This is certainly possible given the uncertainties of the observations.

The observed Lall-sky shows no trend and a high degree of time variability, whereas the models show negative trends that look similar to the fc time series. Since this is the all sky liquid water path, trends will include the effect of varying fc as well as of varying L. The lack of an observed trend might suggest that a small-magnitude fc trend occurred in reality in order to produce the small Lall-sky trend, or it could indicate a compensating small L trend. A small fc trend would be consistent with the small observed FSW↑ trend and might indicate that the PATMOSx fc trend is more accurate so that the model fc trend magnitude is overestimated.

The surface temperatures in the model are too low, and the trends for most ensemble members and the ensemble means are too steep. However, there is a high degree of variability across the ensemble members, and some of the ensemble members do agree with the observations. The ensemble mean temperature trend being too steep is consistent with a picture of too much cloud reduction via cloud feedbacks to temperature, which would in turn cause too strong a reduction in fc, Lall-sky and FSW↑, which is consistent with the other results described in this section. It indicates that the model climate sensitivity is too strong, which may be related to the N. Atlantic cloud feedback as also suggested in but could also be due to unrelated factors.

In this study we used the HadGEM global coupled climate model and the UKESM1 Earth system model to explore the factors driving historical changes in FSW↑ for the North Atlantic region for ocean grid boxes that contained little sea ice. We found that there is a positive trend in FSW↑ between 1850 and 1970 and then a negative trend until 2014. The analysis shows that the pre-1970 trend is mainly driven by an increase in cloud droplet concentrations (Nd) due to increases in aerosol emissions, and the trend in the later period is mainly driven by a decrease in cloud fraction, likely due to cloud feedbacks caused by greenhouse gas-induced warming.

We also examined the relative effects of aerosol radiative forcing and climate feedbacks on the change in FSW↑. In the pre-1970 period, aerosol-induced cooling and greenhouse gas warming roughly counteracted each other so that there was little cloud feedback effect. Therefore, in this period aerosol forcing is the dominant cause of changes in FSW↑. However, in the post-1970 period the warming from greenhouse gases intensified, leading to a large warming over the North Atlantic and reduction in FSW↑ from cloud feedbacks. Combined with a reduction in aerosol forcing during this period, this led to temperature feedbacks dominating over the aerosol forcing. This is summarized in the schematic of Fig. . These results suggest that it is unfeasible to use the post-1970 period (during which there are useful satellite observations) to evaluate and constrain ACIs but that cloud feedbacks might be usefully evaluated, although it may be possible to identify smaller regions or specific times during the satellite era when the aerosol effects are stronger, e.g. when temperature changes are small.

Comparisons to satellite observations between 1985 and 2014 indicate that the model reduction in FSW↑ is too strong for both UKESM1 and HadGEM. The simulated increase in temperature during this period is also too strong. We analysed the extent to which the too-strong temperature trend could explain the excess ΔFSW↑ via cloud feedbacks. However, we find that the bias in temperature trend can only account for part of the ΔFSW↑ discrepancy given the estimated model feedback strength (λ=∂FSW∂T). This suggested that UKESM1 and HadGEM have positive biases in λ or that the negative aerosol effective radiative forcings are too strong (a too-strong aerosol forcing would produce a positive bias in the temperature increase during the 1985–2014 period because aerosol emissions declined). A λ value that is too negative (too strong a cloud feedback) would directly impact the equilibrium climate sensitivity of the model (producing too much warming for a given forcing). Hence, biases in either the aerosol forcing or the feedback strength would have large implications for future climate projections for these models.

The analysis also hints that the pattern effect, whereby a particular spatial pattern of SSTs has a large influence on λ and climate sensitivity , is not having a large influence on λ for the North Atlantic region. This conclusion is based on the result that ΔFSW↑ from the domain-mean time series for the 1985–2014 period from a simulation that used observed SSTs and sea ice (the atmosphere-only simulation) was similar to estimates made using the UKESM1 and HadGEM coupled model data with the surface temperature changes from the domain-mean time series substituted for the observed temperature change; this suggests that it is the magnitude of the temperature change rather than the spatial pattern that leads to a difference in ΔFSW↑ between the coupled and the atmosphere-only simulations for the North Atlantic. However, the result may not extend to other regions, and uncertainties are large; further work is required to clarify this. Even if there was a large pattern effect, this would still require an explanation of why the model SST trends in the N. Atlantic were too steep and why the model SST pattern was incorrect. It is possible that the natural SST pattern exhibits a high degree of variability such that it might be difficult for a model to simulate the observed pattern, which may have been a low-probability event. We also note that some of the ensemble members did have reasonable N. Atlantic SST trends. On the other hand, the lack of SST agreement could indicate model issues.

If the model cloud feedback strength is too large, then the conclusion (based on the model results) that feedbacks are the dominant cause of the change in FSW↑ during the post-1970 period in the real world would be weakened. However, for the post-1970 period, the ΔFSW↑ value from feedbacks would have to change from -5.4 to -0.83 W m-2 in order for the feedback and aerosol forcing effects to be equal. Therefore, the conclusion is likely to remain robust. On the other hand, if the model aerosol forcing is too large, then using the correct aerosol forcing would enhance the ratio between cloud feedback and aerosol forcing and hence strengthen the conclusions. Furthermore, the strength of the aerosol forcing was decreased during UKESM1 model development , showing that an excessive forcing strength is a long-standing concern of the model developers.

A recent paper examined the individual effects of changes in SSTs/sea-ice extent (SIE), aerosol emissions and GHG emissions for a similar region to that studied here. They used the Met Office GA6.0 atmosphere and land model , which is an older version of the climate model used in this study. They used atmosphere-only simulations with SSTs taken from observations and examined differences between 2000–2015 time averages and 1980–1985 time averages, which is within the post-1970 analysed in our paper. They focused on the June, July and August (JJA) period. Their results showed that aerosol emission changes dominated the change in downwelling surface solar radiation (SSR) with little influence from SSTs/SIE or GHGs. The lack of influence from SSTs/SIE for that period is in contrast to our results where the cloud feedbacks (driven by SST changes) dominated over aerosol forcing in terms of producing changes in FSW↑ (and presumably SSR too). This difference in results could be due to a number of reasons. One is their use of observed SSTs in contrast to our simulations where the SSTs were predicted by the coupled ocean model. We showed earlier that the SST trends in our coupled model simulations for the post-1970 period were too strong, although correcting for that bias did not change our conclusions. Another potential reason is that there have been a number of advancements of the model between the version used in and that used in our paper. Those changes are likely to have affected the model feedback responses as well as the aerosol responses; hence, a different balance of aerosol forcing to feedbacks is perhaps expected. Finally, they focused on the JJA season, whereas we used annual averages. Further work is recommended to determine the reasons for these differences as well as to examine differences amongst various other models.

A final interesting implication that follows from our results is that the appearance of coincident peaks in the Nd and FSW↑ time series from the UKESM1 and HadGEM models at around 1970 is due to chance. The decrease in FSW↑ after 1970 is almost entirely caused by the growing effects of greenhouse gas emissions on the larger-scale atmospheric and/or ocean circulation rather than the decrease in aerosols that also starts around 1970. Hence if the greenhouse gas-related effects were shifted to earlier or later in the time series (e.g. due to the rapid increase in greenhouse gas emissions occurring earlier or later), we would expect the decline in FSW↑ to occur correspondingly earlier or later such that the peaks would no longer be coincident. This can be contrasted to the situation over land where the turning point in surface SW flux has been associated with a decline in aerosol emissions .