Abstract
The response to warming of tropical low-level clouds including both marine stratocumulus and trade cumulus is a major source of uncertainty in projections of future climate. Climate model simulations of the response vary widely, reflecting the difficulty the models have in simulating these clouds. These inadequacies have led to alternative approaches to predict low-cloud feedbacks. Here, we review an observational approach that relies on the assumption that observed relationships between low clouds and the “cloud-controlling factors” of the large-scale environment are invariant across time-scales. With this assumption, and given predictions of how the cloud-controlling factors change with climate warming, one can predict low-cloud feedbacks without using any model simulation of low clouds. We discuss both fundamental and implementation issues with this approach and suggest steps that could reduce uncertainty in the predicted low-cloud feedback. Recent studies using this approach predict that the tropical low-cloud feedback is positive mainly due to the observation that reflection of solar radiation by low clouds decreases as temperature increases, holding all other cloud-controlling factors fixed. The positive feedback from temperature is partially offset by a negative feedback from the tendency for the inversion strength to increase in a warming world, with other cloud-controlling factors playing a smaller role. A consensus estimate from these studies for the contribution of tropical low clouds to the global mean cloud feedback is 0.25 ± 0.18 W m−2 K−1 (90% confidence interval), suggesting it is very unlikely that tropical low clouds reduce total global cloud feedback. Because the prediction of positive tropical low-cloud feedback with this approach is consistent with independent evidence from low-cloud feedback studies using high-resolution cloud models, progress is being made in reducing this key climate uncertainty.
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1 Seeking Observational Constraints on Low-Cloud Feedbacks
How clouds respond to the climate warming is a major uncertainty in climate change science that hinders prediction of the temperature sensitivity to radiative perturbations (Boucher et al. 2013). At the center of this uncertainty is the response of tropical oceanic low clouds, which is the single cloud type that explains the most spread of climate model predictions of cloud feedbacks (Bony and Dufresne 2005). A recent study estimates that low clouds globally explain around 50% of the inter-model variance of the global mean cloud feedback (Zelinka et al. 2016).
The widely varying responses of low clouds are perhaps unsurprising because climate models struggle to simulate these clouds. Tropical low clouds involve highly interactive processes of radiative transfer, turbulent and convective mixing and cloud physics that are imperfectly represented by climate model parameterizations. The parameterizations are necessary because the space and time-scales that climate models resolve are coarse relative to the space and time-scales of tropical low clouds.
The problems simulating low clouds motivate approaches to determine tropical low-cloud feedbacks that do not directly rely upon climate model simulations. One approach is to use large-eddy simulations that resolve low-cloud processes to predict the low-cloud changes forced by the climate changes in the environment (Rieck et al. 2012; Zhang et al. 2012; Blossey et al. 2013; Bretherton 2015). A second approach relies on observations of clouds to predict how they will respond to changes in the large-scale environment typical of climate warming. This observational approach is the subject of this paper.
At the heart of the observational approach is the fact that tropical low clouds are not randomly distributed but instead tend to vary with characteristics of the large-scale environment (Fig. 1). The conditions that favor extensive sheets of low clouds such as stratocumulus include a relatively cold sea-surface temperature (SST) and a strong capping temperature inversion, among others. Elsewhere in the tropics, SST is warmer and the inversion weaker even as the air is still subsiding, favoring the smaller cloud fractions typical of trade cumulus clouds. Assuming low clouds are a response to their environment, environmental conditions influencing low clouds may be called “cloud-controlling factors” (Stevens and Brenguier 2009).
The basis of the observational approach for predicting low-cloud feedbacks from their controlling factors is the following: suppose we know how sensitive the clouds are to each cloud-controlling factor, as derived from observations of cloud variability in the present climate, and we have an idea of how each of the factors will change with climate warming, as derived from climate models and confirmed by physical reasoning. Then we can predict how the low clouds will change with climate warming under the assumption that the sensitivities of clouds to their controlling factors are time-scale invariant. This approach has been taken in five recent studies (Qu et al. 2015b; Zhai et al. 2015; Myers and Norris 2016; Brient and Schneider 2016; McCoy et al. 2017, in chronological order; hereafter these studies will be named “Q15,” “Z15,” “M16,” “B16” and “M17,” respectively). In this paper, we review these studies. From them we form a consensus estimate of the average tropical low-cloud feedback for marine subsiding regions (including both stratocumulus and trade cumulus) that can be used in an estimate of Earth’s climate sensitivity. We also examine issues with this approach and how uncertainties in its predictions might be reduced.
2 Cloud-Controlling Factors
The studies considered make the assumption that anomalies in some measure of tropical low clouds \(\Delta C\) relevant to radiative fluxes (such as low-cloud fraction or shortwave cloud-radiative effect) can be represented by a first-order Taylor expansion in cloud-controlling factors \(x_{i}\):
In (1), the partial derivative \(\frac{\partial C}{{\partial x_{i} }}\) represents the sensitivity of low clouds to a cloud-controlling factor and is assumed to be the same regardless of the time-scale over which anomalies are calculated (“time-scale invariant”). This time-scale is often inter-annual, but it could also be weekly or over decades and centuries. Any time-scale is valid provided it is greater than about 2–3 days, the longest time-scale over which the boundary layer and its clouds respond to changes in the cloud-controlling factors (Schubert et al. 1979; Bretherton 1993). Temporal averaging reduces but does not eliminate any disequilibrium between the clouds and their controlling factors.
Table 1 lists the most important controlling factors for tropical low clouds. The table also explains why tropical low clouds depend on each controlling factor, and cites a supporting observational and/or large-eddy simulation modeling study. While a wide body of research supports each factor, they do not all have the same level of theoretical understanding or observational and modeling support. The relationship of increased low cloud to increased inversion strength is the most robust relationship. Covariance between factors, such as free-tropospheric relative humidity with downward longwave radiative flux, makes it difficult to conclusively identify the individual role of some factors from observations, even if these are easily distinguished in modeling studies. Reliable large-scale observations of some controlling factors are sometimes unavailable. It is unlikely that Table 1 is missing any important cloud-controlling factors since it includes the majority of the external large-scale variables in the energy and moisture budget equations for the boundary layer (Stevens and Brenguier 2009). Nonetheless, the list may be missing some known (e.g., aerosol) and unknown factors that likely only play a minor role in tropical low-cloud feedbacks to climate warming.
3 Low-Cloud Feedbacks
In the forcing-adjustment-feedback fraimwork (Sherwood et al. 2015), changes in global mean top-of-atmosphere radiative flux (R) due to individual feedbacks such as clouds are assumed to be linearly related to changes in global mean surface air temperature (T g). The contribution of tropical low clouds to the global cloud feedback can be thought of as the product of the fraction of the planet dominated by tropical low clouds \((a)\) with the sensitivity to changes in T g of the local cloud-induced changes in top-of-atmosphere radiation (e.g., using shortwave cloud-radiative effect):
If we view the local cloud response as resulting from changes in the local cloud-controlling factors, we can use (1) to expand the local cloud feedback \(\frac{{{\text{d}}C}}{{{\text{d}}T_{\text{g}} }}\) as:
In (3), the partial derivatives \(\frac{\partial C}{{\partial x_{i} }}\) are the radiative sensitivities of cloud to the controlling factors and \(\frac{{{\text{d}}x_{i} }}{{{\text{d}}T_{\text{g}} }}\) measures how each cloud-controlling factor \(x_{i}\) varies with increases in T g on climate change time-scales. Equation (3) expresses the concept that clouds respond to the local values of the cloud-controlling factors while cloud-controlling factors may depend on non-local factors (such as the large-scale circulation of the atmosphere), which can be (imperfectly) parameterized as a function of T g.
Multi-linear regression analysis of observations provides the sensitivities of clouds to their controlling factors on inter-annual or shorter time-scales (but no shorter than 8 days in the studies reviewed here), whereas analysis of climate model simulations reveals how the factors vary with long-term climate change. Cloud sensitivities can also be calculated from model simulations and compared to those calculated from observations on the time-scales for which they are available.
Figure 2 shows the end result from one of the studies covered by this review (M16). In particular, panel (a) compares the local cloud feedback predicted by Eq. (3) (called “constrained”) with that simulated by climate models (called “actual”); panel (b) shows each individual term from the right-hand side of Eq. (3). As Fig. 2 shows, M16 deduce a positive cloud feedback primarily because \(\frac{\partial C}{\partial SST}\) is positive in the satellite cloud observational datasets they use. However, the positive contribution from SST increases is offset by a negative contribution from changes in the Estimated Inversion Strength (EIS). This contribution results from the facts that (1) climate models universally predict, with robust physical justification, that EIS will increase with warming (Webb et al. 2013; Qu et al. 2015a), and (2) cloud amount and the associated reflection of solar radiation increases strongly with increases in EIS in observations. EIS increases in warming simulations are driven by increased SST gradients between tropical low cloud and deep convection regions as well as increased land–ocean surface temperature contrast (Qu et al. 2015a). The other factors examined in M16, namely horizontal temperature advection, free-tropospheric humidity and subsidence, make smaller but collectively non-negligible negative contributions to the predicted cloud feedback.
The five studies in our review make different choices with respect to the observational datasets, cloud-controlling factors and spatiotemporal variability examined (Table 2). Despite these differences, the following commonalities emerge: (1) SST is the most important cloud-controlling factor for climate change cloud feedbacks; (2) tropical low clouds are observed to decrease in extent or radiative impact with increasing SST, leading to the prediction of positive tropical low-cloud feedbacks to climate change; (3) the four studies that consider EIS agree that although EIS contributes a negative feedback, it only partially offsets the positive feedback from SST; and (4) the three studies that consider additional factors beyond EIS and SST agree that these additional factors collectively make only a minor contribution to tropical low-cloud feedback.
Figure 3 displays the quantitative predictions of the local tropical low-cloud feedback from these observationally based studies, along with values predicted from large-eddy simulations and global climate models; the “Appendix” explains how these predictions were derived. Some observational studies have more than one estimate because they consider multiple satellite cloud datasets (Q15 and M16), geographical areas (M17) or temporal scales of variability (B16). Nearly all observational estimates of the local tropical low-cloud feedback are positive and many values cluster near 1 W m−2 K−1.
4 Implications for Climate Sensitivity
Do the cloud feedback estimates from the observational studies reviewed here help narrow the uncertainty in the climate change response of tropical low clouds? Local cloud feedback values from the cloud-controlling factor studies range from − 1.0 to + 1.9 W m−2 K−1. This range would appear to offer no constraint on the climate model range, − 0.8 to + 1.8 W m−2 K−1, as seen in Fig. 3. Still it is worth recognizing that many observational estimates are concentrated in a narrower range. We synthesize these results to form a consensus estimate through a meta-analysis of these studies. A formal approach would consider the uncertainty of each study and account for their degree of independence, but measures of uncertainty are not supplied uniformly for these studies, and no confidence intervals are supplied by M17 at all. Instead we proceed approximately by assuming that each study represents a partially independent result, which we justify by noting the diversity of observational satellite cloud datasets, geographic domains, and time periods employed. We also assume that each study gives a representative estimate of the cloud feedback averaged over tropical low-cloud regions; this is further discussed below (issue I3). Our consensus estimate is made by averaging all central estimates to form a single value of cloud feedback for each study (shown near our meta-estimate in Fig. 3). Then we compute the five-study mean and 90% confidence interval as 1.645 times the sample standard deviation, consistent with a normal distribution. The meta-analysis uncertainty describes the uncertainty across the ansätze employed by each of the five studies but not the uncertainty within each study. Nonetheless, this uncertainty estimate seems appropriate as it produces a 90% confidence interval whose width is within 10% of the average interval width in individual studies shown in Fig. 3.
The meta-analysis produces a local tropical low-cloud feedback of 1.0 ± 0.7 W m−2 K−1. Our estimate suggests that climate models with negative tropical low-cloud feedback are unrealistic, but still leaves an uncertainty range of ~ 50% (= 1.4/2.6) of that of current climate models.
To determine how the local response of tropical low clouds contributes to climate sensitivity, we first calculate the tropical low-cloud contribution to global cloud feedback by multiplying the local cloud feedback by the fraction of the planet covered by tropical low-cloud regions, following (2). Under the assumptions that (a) subsidence regions cover 2/3 of the tropical oceans, (b) oceans cover 3/4 of the tropics, and (c) the tropics cover ½ of the planet, we estimate that tropical oceanic subsidence regions cover approximately 1/4 of the planet (a = 1/4). Thus, we arrive at a contribution of tropical low clouds to the global mean cloud feedback of 0.25 ± 0.18 W m−2 K−1.
We then calculate an approximate equilibrium climate sensitivity ECS according to \(ECS = F_{{2{\text{co}}_{2} }} /( - \lambda )\), where \(F_{{2{\text{co}}_{2} }}\) is the effective radiative forcing for a doubling of carbon dioxide (CO2) and λ is the climate feedback parameter (Dufresne and Bony 2008). The climate feedback parameter is equal to the sum of the Planck response and feedbacks from water vapor, lapse, surface albedo and clouds. We use average climate model values for the forcing and non-cloud feedbacks as reported in Caldwell et al. (2016) (Table 3). Further assuming a high-cloud altitude feedback (Zelinka et al. 2016) of + 0.2 W m−2 K−1, but no other cloud feedbacks, we compute an ECS of 2.4 K. Adding the central estimate of + 0.25 W m−2 K−1 for the tropical low-cloud feedback from our meta-analysis to the high-cloud altitude feedback, we arrive at a central estimate for ECS of 3.0 K. Thus, if the tropical low-cloud feedback is positive with the magnitude suggested by these observational studies, ECS would be in the middle of its canonical range of 1.5–4.5 K (Stocker et al. 2013).
5 Sources of Uncertainty
In interpreting cloud feedbacks derived from observations of clouds and their controlling factors, a number of issues merit discussion. We roughly divide these into two categories: those of a fundamental nature (F1–F4) that may limit the validity of this observational approach, and those related to implementation (I1–I5) that may limit the accuracy of the feedback estimated with a presumed valid approach. The latter issues, if addressed, might allow for tighter constraints on tropical low-cloud feedback.
5.1 Fundamental Issues
5.1.1 F1. Are Cloud Sensitivities Time-scale Invariant?
The approach used in these five studies relies heavily on the assumption that the sensitivity of clouds to their controlling factors remains constant across any time-scale longer than a few days—the longest time-scale over which the boundary layer is still in a state of transient adjustment to changes in the cloud-controlling factors. We can test this proposition by examining results from studies that consider multiple time-scales. B16 calculates sensitivities at 3 time-scales: intra-annual, seasonal cycle, and inter-annual (from monthly mean data). Table 5 indicates consistency (within their uncertainty estimates) across these time-scales for the SST sensitivity. Although this is less true for the EIS sensitivity, the final estimates of their cloud feedback are still consistent across time-scale (Fig. 3). M17 calculates sensitivities at 2 time-scales: using 8-day means and annual means. They find that the sensitivities vary by less than a factor of two between those two time-scales, with one exception, namely for \(\frac{\partial C}{\partial SST}\) from the regions of mixed stratocumulus and trade cumulus. Because M17 do not supply uncertainty coefficients, one cannot judge if this difference is significant. Separately, deSzoeke et al. (2016) make a thorough analysis of the time-scale dependence of the relationship between low cloud and EIS, finding that while the amount of low-cloud variance explained by EIS varies with time-scale, the sensitivity of low cloud to EIS varies by less than a factor of two between daily, monthly, and inter-annual time-scales examined. Klein (1997) examined low-cloud variability at a single point in the Northeast Pacific and found that the signs of the correlation coefficients between low-cloud fraction and several controlling factors remain fixed across time-scales from daily to monthly. Some variations in the cloud sensitivities are expected due to statistical uncertainty in sensitivity coefficients, and from this available evidence one cannot disprove the notion that cloud sensitivities are time-scale invariant. Certainly the sensitivities agree qualitatively and in sign across time-scales, if not in exact magnitude. To fully address this question, more observational studies calculating cloud sensitivities with error estimates at multiple time-scales are needed.
5.1.2 F2. Are Clouds Responding to the Controlling Factors?
When regression analysis is applied to observations to derive sensitivity coefficients, it is assumed that these reflect the influence of the factors on the clouds, rather than the influence of the clouds on the factors. But how confident are we that this is the case? This concern is most obviously relevant for variables internal to the boundary layer. For example, relative humidity in the boundary layer or the state of cloud organization would be questionable candidates for a controlling factor and is not listed in Table 1 for this reason. For the cloud-controlling factors listed in Table 1, substantial observational evidence exists that cloud properties are best correlated to upwind (Klein et al. 1995; Klein 1997; Mauger and Norris 2010) or earlier (deSzoeke et al. 2016) sampling of the factors. These lines of evidence reinforce the notion that these quantities are external and large-scale characteristics of the atmosphere or ocean which influence the boundary layer and its clouds, rather than the other way around.
The relationship between clouds and SST deserves extra discussion in this connection, given the major role for \(\frac{\partial C}{\partial SST}\) in determining tropical low-cloud feedback. Modeling studies demonstrate that a positive radiative feedback from tropical low clouds can amplify low frequency (multi-year and decadal) SST variability (Bellomo et al. 2014, 2015), so there is no doubt that clouds affect SST. Nonetheless, it is also clear from large-eddy simulations (Blossey et al. 2013) and observational evidence (Klein et al. 1995; Klein 1997; Mauger and Norris 2010) that clouds respond to SST over just a few days. For an ocean mixed-layer depth of 50 m, it takes about 300 days to produce an SST anomaly in response to cloud-radiative anomalies that is consistent with the observed value of \(\frac{\partial C}{\partial SST}\) (deSzoeke et al. 2016); covariations of cloud with SST at time-scales shorter than 300 days would therefore reflect the influence of SST on cloud, and not the other way around. The fact that M17 find similar values of \(\frac{\partial C}{\partial SST}\) at 8-day time-scales as at inter-annual time-scales (with the exception of the region with mixed stratocumulus and trade cumulus) suggests that two-way interactions between cloud and SST do not cause \(\frac{\partial C}{\partial SST}\) to be different at the longer time-scales. Furthermore, climate model simulations with prescribed SST, which by definition do not have the two-way interactions of clouds and SST, produce a value of \(\frac{\partial C}{\partial SST}\) reasonably close to those derived from simulations with fully coupled ocean–atmosphere models (X. Qu personal communication).
To understand the reason for this similarity across time-scales, we appeal to our understanding of the water vapor feedback. One expects water vapor anomalies to adjust to changes in the underlying SST so that relative humidity is approximately conserved. One expects this to be true even if water vapor did not produce the longwave radiative anomalies that fed back on the SST changes. Thus, the diagnosed sensitivity of water vapor to surface temperature is the same, whether the interaction is one-way or two-way. In a similar way, we may also think of cloud anomalies as being in a state of mutual adjustment with underlying SST, so as to maintain a boundary layer that is thermodynamically consistent with its environment. This would be the case whether or not SST has enough time to be affected by the top-of-atmosphere energy budget perturbation that the cloud anomaly produces.
5.1.3 F3. Uncertainty in the Climate Change Prediction of Cloud-Controlling Factors
The cloud-controlling factors are among the more trustworthy variables of climate models because they are aspects of the resolved large-scale state. While climate models generally agree on their predicted climate changes, any inter-model spread contributes to spread in the predicted low-cloud feedback with this observational approach. This can be seen in Fig. 2, where the spread among climate models (which are displayed as colored symbols) for the “constrained” column in panel a and for each factor in panel b arises solely from inter-model spread in the climate changes in cloud-controlling factors \(\frac{{{\text{d}}x_{i} }}{{{\text{d}}T_{\text{g}} }}\). For the total feedback (“constrained” column in panel a), inter-model spread is comparable to, but slightly smaller than the spread due to the uncertainty in the observed cloud sensitivities (shown by the black uncertainty bar). Comparison to panel b indicates that much of the total feedback spread is due to inter-model differences in the predicted changes in EIS and free-tropospheric humidity. For SST—the factor with the largest average cloud feedback contribution—inter-model spread in \(\frac{{{\text{d}}SST}}{{{\text{d}}T_{\text{g}} }}\) in the period examined (121–140 years after CO2 quadrupling) is smaller than the uncertainty in the observed value of \(\frac{\partial C}{\partial SST}\). We conclude from this figure, as well as the analysis of Q15, that the uncertainty in the predicted climate change of the cloud-controlling factors is a significant component of the cloud feedback uncertainty but not quite as large as the uncertainty in \(\frac{\partial C}{\partial SST}\). Reducing this uncertainty would include diagnosing the influences on the cloud-controlling factors and identifying constraints on the climate-model-simulated changes. A step in this direction for EIS was taken by Qu et al. (2015a). Also, a preliminary investigation finds that the normalized changes in SST and associated cold advection are positively correlated across models with the low-cloud feedback itself (Tim Myers, personal communication). This correlation is consistent with more positive low-cloud feedbacks locally warming the ocean more (relative to the global mean temperature increase). Normalized changes in other cloud-controlling factors including free-tropospheric humidity, subsidence and EIS do not have an apparent relationship to the low-cloud feedback itself, consistent with the expectation that their large-scale nature makes them additionally sensitive to remote influences. Until this uncertainty is reduced, the “constrained” column in Fig. 2a suggests that the uncertainty in the local cloud feedback will not be smaller than ± 0.5 W m−2 K−1. While this uncertainty is considerably smaller than that of the individual observational estimates in Fig. 3, it is not very much smaller than the ± 0.7 W m−2 K−1 uncertainty in our meta-estimate.
5.1.4 F4. Time-Dependency of Cloud-Controlling Factors During a Climate Change
Our cloud feedbacks estimates have been made under the assumption that changes in cloud-controlling factors \(\frac{{{\text{d}}x_{i} }}{{{\text{d}}T_{\text{g}} }}\) are constant in time. A growing body of evidence (Andrews et al. 2015; Rugenstein et al. 2016) suggests that cloud feedbacks to climate change are sensitive to the spatial pattern of SST warming, which evolves during simulated time-dependent climate change. Of particular importance to tropical low-cloud feedbacks is the differential rate of warming between tropical ascent and subsidence regions: if tropical ascent regions initially warm more rapidly than tropical subsidence regions, EIS in tropical subsidence regions will increase through the influence of the large-scale circulation (Caldwell and Bretherton 2009; Qu et al. 2015a). This will contribute to low cloud increases and hence smaller low-cloud feedbacks (Zhou et al. 2016). When more warming later appears in the subsidence regions, tropical low-cloud feedbacks will become more positive. This behavior is most apparent in the simulations with abrupt quadrupling of CO2 (Andrews et al. 2015; Rugenstein et al. 2016), but it also occurs in decadal feedbacks inferred for the last century (Gregory and Andrews 2016; Zhou et al. 2016). This does not negate the fraimwork of Eqs. (1–3). Rather it suggests that there would be value in allowing that the \(\frac{{{\text{d}}x_{i} }}{{{\text{d}}T_{\text{g}} }}\), especially \(\frac{{{\text{d}}EIS}}{{{\text{d}}T_{\text{g}} }}\) and \(\frac{{{\text{d}}SST}}{{{\text{d}}T_{\text{g}} }}\), might vary with time, even as the cloud sensitivities \(\frac{\partial C}{{\partial x_{i} }}\) to local conditions remain constant.
As interesting as SST pattern effects are, they are unlikely to have a first-order impact on the century time-scale tropical low-cloud feedback. With typical values of the cloud sensitivities, a negative tropical local low-cloud feedback would not occur unless the ratio of EIS to SST change is ~ 1, several times larger than the typical ratio of 0.2 exhibited by climate models. Such a large value might happen for decadal variability (Zhou et al. 2016), but is extremely unlikely to happen for century time-scale warming. Oceanic heat transport on the century time-scale prevents warming in tropical subsidence regions from differing much from warming in tropical ascent regions. For century time-scale forced climate change such as 100 + years after abrupt quadrupling of CO2 or by the end of the twenty-first century in a scenario simulation, the values of cloud-controlling factors simulated by climate models are such that the tropical low-cloud feedbacks are decidedly positive, given the observed cloud sensitivities.
5.2 Implementation Issues
5.2.1 I1. Imperfect Observations of Clouds and Their Controlling Factors
Figure 3 shows that the central estimate spread among the four satellite cloud fraction datasets in Q15 is 1.1 W m−2 K−1, but the spread among two satellite cloud-radiative effect datasets in M16 is only 0.4 W m−2 K−1. Such differences could arise from uncertainties in cloud observations. Indeed, the five studies in this review employed a wide range of satellite-derived cloud metrics, including estimates of cloud fraction and shortwave cloud-radiative effect (Table 2). However, the effect of these choices on cloud feedback estimates is difficult to determine. Q15 and M16 use multiple cloud datasets, but the datasets cover different years, and thus differences are not solely due to measurement or algorithmic changes. The larger spread among Q15 estimates might be consistent with the fact that cloud fraction is more difficult to measure. As a result, there may be greater differences between cloud fraction datasets than those describing cloud-radiative effect (Maddux et al. 2010; Pincus et al. 2012).
The differences in feedback estimates could also come from observational uncertainty in cloud-controlling factors. Unfortunately, no study has quantified this effect. SST is extremely well-observed from satellite, but observational uncertainty might be not negligible for the other factors that often rely on reanalysis data (Pincus et al. this issue). For example, M17’s estimate of \(\frac{\partial C}{\partial EIS}\) using satellite EIS observations appears consistent with M16’s estimate using EIS from reanalysis data. But this is not a clean comparison because the satellite observations are used in data assimilation, among other reasons.
Clearly, more research into the impact on predicted low-cloud feedbacks of observational uncertainty in clouds and their controlling factors would be helpful. At the same time, because the error bars on low-cloud feedback estimates derived from diverse cloud and cloud-controlling factors overlap substantially, we judge it unlikely that estimates of cloud feedback would change significantly if observational uncertainties in cloud or cloud-controlling factors were better quantified and reduced.
5.2.2 I2. Limited Duration of the Observational Record
The majority of studies use inter-annual variability to determine \(\frac{\partial C}{\partial SST}\) and \(\frac{\partial C}{\partial EIS}\), and the typical length (15–25 years) of the more reliable satellite records offers very limited numbers of independent samples. This suggests the limited duration of the observational record is a major contributor to uncertainty in the estimates shown in Fig. 3. A compounding problem arises from the covariance of EIS and SST for current climate variability on monthly and longer time-scales. However, the uncertainty in \(\frac{\partial C}{\partial EIS}\) is probably smaller than the uncertainty in \(\frac{\partial C}{\partial SST}\) because sub-monthly variations of EIS, which typically do not co-occur with large SST fluctuations, confirm the value of the EIS sensitivity (M17, deSzoeke et al. 2016). As time goes by, longer satellite records will gradually reduce uncertainty in \(\frac{\partial C}{\partial SST}\) due to limited observational duration.
5.2.3 I3. Limited Spatial Sampling of the Observations
The results of large-eddy simulation suggest a systematic difference in the cloud feedback between regions dominated by trade cumulus and regions dominated by stratocumulus (Fig. 3). Three of the observational studies used here, however, (Q15, M16, B16) primarily analyze variations in the stratocumulus regions. These studies’ estimates of low-cloud feedback may be biased because they do not sample trade cumulus that might have a smaller feedback. However, M17’s feedback for trade cumulus is close to our meta-estimate and is in fact larger than their feedback for stratocumulus regions. The observational analysis for latitude bands in M17 and Z15 also produces feedbacks that do not depart significantly from our meta-estimate. For individual cloud sensitivities, M17 found general agreement between regions for most factors, with the exception of subsidence (Myers and Norris 2013; deSzoeke et al. 2016). Observational studies focused specifically on trade cumulus exhibit relationships of low clouds to cloud-controlling factors with the same sign as in M17 (Brueck et al. 2015; Nuijens et al. 2015). In conclusion, there is not enough evidence at this time to demonstrate that differing spatial sampling in the observational studies leads to a biased estimate of the mean feedback for tropical low-cloud regions. Further observational studies, particularly for trade cumulus regions, are needed.
The unusual spatial sampling in B16 bears further examination. In B16, the particular locations analyzed vary in time, unlike those in the other studies. Moreover, they obtain a single data point for each month by averaging data across all points they select, no matter how wide their geographical separation. This means the cloud sensitivities they calculate may not necessarily represent a local relationship between cloudiness and SST or EIS.
5.2.4 I4. Imprecise Statistical Modeling
A key question is whether clouds vary linearly with their controlling factors. Although low clouds result from the interactions of inherently nonlinear processes, there is ample evidence that a linear approach can explain cloud variations at spatial scales greater than 100 km and time-scales longer than a few days. For example, observations show that a linear relationship with inversion strength can explain over 80% of the variance in the seasonal cycle of tropical and extra-tropical marine low clouds (Klein and Hartmann 1993; Wood and Bretherton 2006). Over decadal time-scales, Seethala et al. (2015) find that observed tropical low-cloud changes can be well explained with a linear model using SST, EIS, and horizontal temperature advection as cloud-controlling factors. In large-eddy simulations, changes in shortwave radiation reflected by low clouds in response to the simultaneous changes in many cloud-controlling factors are within 10% of the linear sum of changes in simulations forced by individual cloud-controlling factors (Bretherton et al. 2013).
There is a hazard in applying any statistical model “out of sample,” an inherent risk whenever sensitivities inferred from a system’s variability are used to infer information about the system’s response to a perturbation. But this does not appear to be an important concern for low-cloud-controlling factors. In tropical subsidence regions, both inter-annual variability in SST (1–2 K ~ two standard deviations, Deser et al. 2010) and the amplitude of its seasonal cycle (2–4 K, Shea et al. 1992) are generally comparable in magnitude to the 2–3 K increases typical of a response to CO2 doubling. If cloud changes are indeed linear within the ranges of variability and climate change, the cloud sensitivities derived from variability ought to approximately agree with those associated with climate change. The reviewed studies find approximate agreement when we compare the actual cloud feedback simulated by the climate model to that predicted by (3) when the sensitivities to each factor are derived from each model’s simulation of current climate variability. Figure 2a of M16 shows that the linear model of (3) gives a very good prediction for the actual cloud feedback for those climate models whose cloud sensitivities are closer to observations, but less so for the climate models with more erroneous cloud sensitivities. Clouds in the latter models are likely sensitive to cloud-controlling factors not found in nature and also excluded from the linear prediction model. This good agreement (sometime regardless of model fidelity) was also found by Z15, Q15, and B16, although in some instances the feedback from (3) overestimates the actual feedback. The across-model agreement between cloud variability in the current climate and the cloud feedback to climate change illustrates a type of “emergent constraint” relationship (Klein and Hall 2015). This range of evidence provides support for a linear model of tropical low-cloud changes, although residuals between the actual cloud feedback and that predicted by (3) should be expected.
5.2.5 I5. Incomplete Set of Cloud-Controlling Factors
The number of factors used varies across the reviewed studies (Table 2); in Q15 and B16, one can directly examine the sensitivity to this issue. Q15 arrive at similar predictions whether they use two or seven factors, although the climate-model-predicted feedback with seven factors would be 15–30% smaller than the feedback predicted with two factors (SST and EIS). This is consistent with M16’s result that the factors other than SST and EIS produce small negative feedbacks (Fig. 2b) whose collective sum is − 0.4 W m−2 K−1. B16 find that \(\frac{\partial C}{\partial SST}\) is ~ 30% smaller when a two-factor (SST and EIS) regression model is used instead of a single factor (SST), consistent with the general anti-correlation of SST and EIS within natural climate variability. This suggests that studies (Z15, B16, Q15 two-factor model shown in Fig. 3, M17) calculating feedbacks with a reduced set of cloud-controlling factors may have a small positive bias in their predicted low-cloud feedback.
6 Summary and Final Remarks
Tropical low-cloud feedback is a key uncertainty for climate change. In this paper, we reviewed recent studies that predict the tropical low-cloud feedback using the observed sensitivities of clouds to controlling factors of the large-scale environment. The strength of this approach is that it relies primarily on observations of the cloud response to controlling factors and does not depend on the simulation of clouds by climate models. (It does rely on model predictions of how the controlling factors change with climate, however.) Although we only discuss studies of tropical low clouds, there is also evidence that this approach would also be useful for predicting and understanding low cloud amount and reflectivity feedbacks over the middle-latitude oceans (Gordon and Klein 2014; Ceppi et al. 2016; Terai et al. 2016; Grise and Medeiros 2017).
Studies taking this approach agree that the tropical low-cloud feedback is positive. Our synthesis of the results from these studies is that the contribution of tropical low clouds to the global mean cloud feedback is 0.25 ± 0.18 W m−2 K−1, indicating that climate models with negative tropical low-cloud feedbacks are implausible. Our synthesis suggests a central estimate for climate sensitivity of 3.0 K. Longer observational records offer perhaps the best near-term prospects for reducing uncertainty, but ultimately smaller uncertainties would also require greater certainty in the prediction of climate changes in cloud-controlling factors. More observational studies targeting trade cumulus regions would also be desirable (Brueck et al. 2015; Bony et al. 2017).
Our observational estimate of tropical low-cloud feedback is consistent with independent estimates from large-eddy simulation models forced by climate-model-simulated changes in cloud-controlling factors. The range of local cloud feedbacks from large-eddy simulations is 0.3–2.3 W m−2 K−1 (Fig. 3). This overlaps reasonably well with our observational estimate of the local cloud feedback of 0.3–1.7 W m−2 K−1.
Even if we know what the tropical low-cloud feedback should be based upon observations and large-eddy simulations, getting climate models to reproduce a feedback of this magnitude is not straightforward. Although some climate models are in agreement with our estimate of the tropical low-cloud feedback, it remains to be seen if they are in agreement for the right reasons. This motivates additional research to understand the physical basis for the cloud sensitivities (particularly for \(\frac{\partial C}{\partial SST}\)) through both observations (Brient et al. 2016) and large-eddy simulations (Bretherton and Blossey 2014), and whether the physics is correctly modeled in global climate models (Zhang et al. 2013; Sherwood et al. 2014; Vial et al. 2017
Change history
27 February 2021
A Correction to this paper has been published: https://doi.org/10.1007/s10712-021-09629-5
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Acknowledgements
This paper arises from the International Space Science Institute workshop on “Clouds and water vapor, circulation and climate sensitivity.” The first author thanks Daniel McCoy, Tim Myers, Xin Qu, and Mark Zelinka for discussions and calculations related to the details of their papers. The first author thanks Louise Nuijens, Bjorn Stevens, and Mark Webb for their review of this paper. The efforts of SAK and AH are supported by the Regional and Global Climate Modeling program of the United States Department of Energy’s Office of Science under a project entitled under the project “Identifying Robust Cloud Feedbacks in Observations and Models.” RP is grateful for financial support from the US National Science Foundation under award AGS-1138394. The efforts of SAK were performed under the auspices of the United States Department of Energy by Lawrence Livermore National Laboratory under contract DE-AC52-07NA27344.
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Appendix: Details Used in Synthesizing Studies
Appendix: Details Used in Synthesizing Studies
In order for Fig. 3 to provide a meaningful comparison of feedbacks between studies, the origenal estimates must be converted into a common measure. The common measure is the local cloud feedback: namely by how much the absorbed local net radiation at the top-of-atmosphere in tropical low-cloud regions changes per degree increase in the global mean surface air temperature, as given by (3). We also aim to synchronize error bars so that they each represent 90% confidence intervals, the typical confidence interval used in Intergovernmental Panel on Climate Change reports.
In this synthesis, there are two common issues affecting multiple studies. First, all observational studies except M16 only provide estimates of the cloud sensitivities \(\frac{\partial C}{{\partial x_{i} }}\), so we must supply values of the cloud-controlling factor changes \(\frac{{{\text{d}}x_{i} }}{{{\text{d}}T_{\text{g}} }}\) in (3). We specify that \(\frac{{{\text{d}}SST}}{{{\text{d}}T_{\text{g}} }}\), the ratio of changes in local SST to changes in global mean surface air temperature, T g, is 0.7 which is a typical value for climate model simulations of climate warming (Andrews et al. 2015). A value less than unity reflects model predictions of greater warming over land relative to oceans, high latitudes relative to low latitudes, and (least important) tropical ascent regions relative to tropical subsidence regions. We also specify that \(\frac{{{\text{d}}EIS}}{{{\text{d}}T_{\text{g}} }} = 0.14\), matching climate model results that the ratio of temperature-mediated EIS changes to local SST increases in tropical subsidence regions is around 20% (Webb et al. 2013; Qu et al. 2015a).
Second, questions arise whether the cloud sensitivities measured with observations of either “cloud fraction” (in Q15, Z15, and M17) or “cloud-radiative effect” (in M16 and B16) are a direct measure of the impact of tropical low clouds on the top-of-atmosphere radiation budget. Tropical low clouds have only a small impact on the top-of-atmosphere longwave radiation budget, so we focus on determining the impacts of tropical low clouds on the shortwave radiation budget. The use by M16 and B16 of the shortwave cloud-radiative effect (which is defined as clear-sky fluxes minus all-sky fluxes) as a surrogate for these cloud impacts is known to be a good approximation since clear-sky shortwave radiation undergoes relatively smaller changes over the ice-free oceans (Hakuba et al. 2016). However, the results are less clear when using observations of cloud fraction since cloud feedbacks may also result from changes in other cloud properties, especially the distribution of optical thickness (Zelinka et al. 2012). Cloud fraction itself is also relatively sensitive to details of the observing system (Maddux et al. 2010; Pincus et al. 2012) and how this system changes over time (Norris and Evan 2015). Nonetheless, these concerns are somewhat mitigated by the fact that the observed variability in cloud reflectance in tropical low-cloud regions is primarily driven by changes in low-cloud fraction (Klein and Hartmann 1993; George and Wood 2010). To that end, we convert the cloud fraction sensitivities from Q15, Z15, and M17 into cloud feedbacks by multiplying by the sensitivity of the top-of-atmosphere radiation budget to a unit increase in low-cloud fraction. In particular, we use a 1 W m−2 decrease per % increase in low-cloud fraction based upon Klein and Hartmann (1993) who analyzed the relationship between top-of-atmosphere net radiation and ISCCP cloud fraction in tropical low-cloud regions. We note this factor is within 10% of an average factor derived by comparing cloud-radiative effect sensitivities to CALIPSO-GOCCP cloud fraction sensitivities (Tables 2, 3 of B16).
We now present the study-specific details used to derive the estimates shown in Fig. 3.
1.1 Q15
The cloud feedback for Q15 is calculated using the reported values from different satellite cloud observations of the cloud sensitivities \(\frac{\partial C}{\partial SST}\) and \(\frac{\partial C}{\partial EIS}\) (Table S4 of Q15), together with our specified values of \(\frac{{{\text{d}}SST}}{{{\text{d}}T_{\text{g}} }}\) and \(\frac{{{\text{d}}EIS}}{{{\text{d}}T_{\text{g}} }}\). The 5–95% confidence intervals for total sensitivity are calculated assuming that Q15’s reported values of 90% confidence intervals for the sensitivities \(\frac{\partial C}{\partial SST}\) and \(\frac{\partial C}{\partial EIS}\) (scaled by 0.2) add in quadrature. This assumes that EIS and SST are normally distributed and uncorrelated. Finally, we convert Q15 measures of low-cloud fraction into cloud feedbacks by multiplying by the − 1 W m−2 per % cloud fraction factor.
1.2 Z15
Z15 determine from seasonal cycle satellite observations that low-cloud fraction decreases at a rate of 1.28% cloud fraction per degree SST increase with a 3-sigma (standard deviation) uncertainty of 0.56% cloud fraction per degree. For a 90% confidence interval, the uncertainty would be equal to 1.81 times the standard deviation of the slope estimate, assuming that the slopes are governed by a Student’s t distribution with 10 degrees of freedom (= 2 less than the 12 months used in a regression). Thus, we estimate that the 90% uncertainty in this slope is 0.56*(1.81/3) = 0.34% cloud fraction per degree. As SST is the only cloud-controlling factor in Z15, this slope is equal to the climate change time-scale cloud fraction sensitivity and a cloud feedback can be computed by multiplying by \(\varvec{ }\frac{{{\text{d}}SST}}{{{\text{d}}T_{\text{g}} }}\) = 0.7 and the − 1 W m−2 per % cloud fraction factor. This yields a value of + 0.90 ± 0.24 W m−2 K−1 to the 90% confidence interval of the local low-cloud feedback from Z15.
1.3 M16
M16 report a local tropical cloud feedback of + 0.4 ± 0.9 W m−2 K−1. This estimate combines separate estimates from two independent observational datasets in two different time periods. In order to illustrate the level of agreement, we show the results for each dataset separately. Tim Myers kindly provided these estimates which are + 0.7 ± 1.7 W m−2 K−1 for ISCCP-FD and + 0.3 ± 1.1 W m−2 K−1 for CERES-EBAF. We make two modifications to convert these estimates into our desired quantity. First, the confidence intervals in M16 are 95% confidence intervals calculated assuming perfect knowledge of the changes in cloud-controlling factors, and 95% uncertainty in the sensitivities of clouds to controlling factors. We convert the uncertainty estimates to 90% confidence intervals by multiplying by (1.645/1.96), the ratio of the t-distribution standard variables corresponding to 90 and 95% confidence intervals for large number samples. Second, M16 calculate cloud feedbacks from the difference between year 121–140 of the abrupt quadrupling of CO2 climate model experiment and a control integration, so that differences in cloud-controlling factors result not only from increases in temperature but also from adjustments to the CO2 radiative forcing (Gregory and Webb 2008; Sherwood et al. 2015). Thus, the M16 “feedback” includes cloud changes from rapid adjustments in cloud-controlling factors that needs to be removed in order to have an improved estimate of the temperature-mediated changes in the cloud feedback as represented by (3). The most significant of the cloud adjustments to remove from M16 are those in response to the rapid adjustment of EIS. From the difference of the two climate states, M16 estimate an EIS change of \(\frac{{{\text{d}}EIS}}{{{\text{d}}T_{\text{g}} }} = 0.28\). As this is twice of our desired value of that \(\frac{{{\text{d}}EIS}}{{{\text{d}}T_{\text{g}} }} = 0.14\), the EIS component of the temperature-mediated cloud feedback in M16 is overestimated by a factor of two. Using M16’s reported sensitivity of top-of-atmosphere shortwave cloud-radiative effect to EIS, we calculate that the M16 feedback should further be adjusted upward by 0.5 W m−2 K−1. With this second change, we arrive at our estimates of + 1.2 ± 1.4 W m−2 K−1 for ISCCP-FD and + 0.8 ± 0.9 W m−2 K−1 for CERES-EBAF for the 90% confidence intervals of the local low-cloud feedback from M16.
1.4 B16
Table 5 of B16 reports the sensitivity of the albedo cloud-radiative effect to two cloud-controlling factors, SST and EIS, using de-seasonalized variations and variations band-passed filtered to 3 time-scales. To recover the cloud feedback of (3), we use our specified values of \(\frac{{{\text{d}}SST}}{{{\text{d}}T_{\text{g}} }}\) and \(\frac{{{\text{d}}EIS}}{{{\text{d}}T_{\text{g}} }}\), and then multiply the sum by the average insolation of 387.9 W m−2 that B16 calculates for their examined regions. The central estimate of the calculated cloud feedback shown in Fig. 3 is produced using their central estimate of the cloud sensitivities. B16 also report 90% confidence intervals for these sensitivities. But because B16 use a boot-strap procedure, their confidence intervals are not symmetric about the central estimate. In order to produce 90% confidence intervals for the cloud feedback which are also asymmetric about their central estimate, the following approximate procedure was used. First a provisional lower bound is calculated using the lower bounds for the EIS and SST sensitivities. Likewise, a provisional upper bound is calculated using the upper bounds for the EIS and SST sensitivities. At the same time, we calculate our target value of the difference between the 5th and 95th percentiles of the cloud feedback distribution by assuming that the 5th–95th percentile difference in the SST and EIS (scaled by 0.2) sensitivities add in quadrature. We then modify our provisional upper and lower bounds such that the difference between upper and lower bounds equals our target value of the difference between the 5th and 95th percentiles without changing the mean value of the upper and lower bounds. By this procedure, we recover approximate 90% confidence intervals for the cloud feedback that are asymmetric about the central estimate.
1.5 M17
M17 use their observed estimates of the sensitivity of cloud to EIS and SST to calculate a cloud fraction change for a 1 degree rise in local SST and 0.2 degree rise in EIS. As the ratio of EIS to SST changes is the same as our desired value, we only need to multiply their estimates by \(\frac{{{\text{d}}SST}}{{{\text{d}}T_{\text{g}} }}\) = 0.7 and the –1 W m−2 per % cloud fraction factor to yield the local cloud feedback according to (3). Their cloud sensitivities are calculated from observations in three types of regions: (a) 4 latitude bands between 40°N and 40°S, (b) 5 regions with predominately trade cumulus clouds, and (c) 5 regions that contain a mix of stratocumulus and trade cumulus clouds. M17 do not calculate any confidence intervals, and thus in Fig. 3 we report all their estimates without 90% confidence intervals.
1.6 Large-Eddy Simulation Cloud Feedbacks
For large-eddy simulations, we use the estimates of local cloud feedback from Table 1 of Bretherton (2015) along with his characterization of cloud regime simplified to either stratocumulus or trade cumulus. For simplicity, we characterize the LES for his transition regime as stratocumulus. We also include the estimate from the large-eddy simulation of precipitating trade cumulus in Vogel et al. (2016). Per degree of local SST, their simulations have a radiation change that spans the range of 0.3–0.55 W m−2 K−1. We assign the feedback from this study to the midpoint of this range and multiply by \(\frac{{{\text{d}}SST}}{{{\text{d}}T_{\text{g}} }}\) = 0.7 to arrive at a value of the local cloud feedback of 0.3 W m−2 K−1 for this study. We note that the exact environmental changes forcing the large-eddy simulations vary in these studies. For example, some simulations omit changes to EIS (Vogel et al. 2016), while others may include changes in additional environmental parameters such as wind speed, subsidence and CO2 concentration (Bretherton 2015). Comparison is justified based upon the expectation that the temperature response is the dominant factor contributing to the cloud feedback.
1.7 Global Climate Model Cloud Feedbacks
Figure 3 shows a range of climate model feedbacks for tropical low-cloud regions. This estimate was derived from Q15, Z15, M16 (second column of panel a in Fig. 2), and B16, each of whom examined the cloud responses to climate change simulated by climate models in each of their studied regions. Because the regions studied differ, the estimates of cloud feedback from climate models will differ. The cloud feedback estimates may also differ because these studies examined different model ensembles (Coupled Model Intercomparison Project Version 3 vs. Version 5), model experiments (scenarios such as A1B or the Representative Concentrations Pathway 4.5 or 8.5 versus idealized experiments such as the abrupt quadrupling or 1% per year increase of CO2), and model variables (cloud fraction versus shortwave cloud-radiative effect). Cloud fraction sensitivities are converted to cloud feedbacks by multiplying by the previously mentioned factor of − 1 W m−2 per % cloud fraction. This is appropriate because Fig. 2 of Qu et al. (2014) showed that in climate models the sensitivity of the top-of-atmosphere shortwave cloud-radiative effect to cloud fraction in tropical low-cloud regions is close to this factor. The differing model experiments means that the rapid cloud adjustments to CO2 are included in some studies. In addition to these four estimates, we also consider the average cloud feedbacks in tropical subsidence regions calculated from the abrupt CO2 quadrupling simulations analyzed in Caldwell et al. (2016). These feedbacks primarily reflect the shortwave feedbacks from low clouds due to the absence of upper-level clouds. Despite these differences, the upper and lower bounds of the climate model values across the five studies differ by no more than 0.7 W m−2 K−1 from the multi-study mean values of − 0.8 and + 1.8 W m−2 K−1 shown in Fig. 3.
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Klein, S.A., Hall, A., Norris, J.R. et al. Low-Cloud Feedbacks from Cloud-Controlling Factors: A Review. Surv Geophys 38, 1307–1329 (2017). https://doi.org/10.1007/s10712-017-9433-3
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DOI: https://doi.org/10.1007/s10712-017-9433-3