ARTICLE

Received 15 Apr 2016 | Accepted 25 Nov 2016 | Published 11 Jan 2017

Adriaan J. Teuling1, Christopher M. Taylor2,3, Jan Fokke Meirink4, Lieke A. Melsen1, Diego G. Miralles5,6, Chiel C. van Heerwaarden7, Robert Vautard8, Annemiek I. Stegehuis8, Gert-Jan Nabuurs9& Jordi Vil-Guerau de Arellano7

Forests impact regional hydrology and climate directly by regulating water and heat uxes. Indirect effects through cloud formation and precipitation can be important in facilitating continental-scale moisture recycling but are poorly understood at regional scales. In particular, the impact of temperate forest on clouds is largely unknown. Here we provide observational evidence for a strong increase in cloud cover over large forest regions in western Europe based on analysis of 10 years of 15 min resolution data from geostationary satellites. In addition, we show that widespread windthrow by cyclone Klaus in the Landes forest led to a signicant decrease in local cloud cover in subsequent years. Strong cloud development along the downwind edges of larger forest areas are consistent with a forest-breeze mesoscale circulation. Our results highlight the need to include impacts on cloud formation when evaluating the water and climate services of temperate forests, in particular around densely populated areas.

1 Hydrology and Quantitative Water Management Group, Wageningen University & Research, Droevendaalsesteeg 3a (Lumen Building), 6708PA Wageningen, The Netherlands. 2 Centre for Ecology and Hydrology, Wallingford OX10 8BB, UK. 3 National Centre for Earth Observation, Wallingford OX10 8BB, UK. 4 Royal Netherlands Meteorological Institute, 3730AE De Bilt, The Netherlands. 5 Department of Earth Sciences, VU University, 1081HV Amsterdam, The Netherlands. 6 Laboratory of Hydrology and Water Management, Ghent University, B-9000 Ghent, Belgium. 7 Meteorology and Air Quality Group, Wageningen University & Research, Wageningen 6708PA, The Netherlands. 8 LSCE/IPSL, Laboratoire CEA/CNRS/UVSQ, 91191 Gif-sur-Yvette, France. 9 Environmental Research (Alterra), Wageningen University & Research, 6708PA Wageningen, The Netherlands. Correspondence and requests for materials should be addressed to A.J.T. (email: mailto:[email protected]

Web End [email protected] ).

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Observational evidence for cloud cover enhancement over western European forests

ARTICLE NATURE COMMUNICATIONS | DOI: 10.1038/ncomms14065

Forests are globally valued for their role in mitigating climate change through their ability to store large quantities of carbon13. Forests also have an impact on the global climate

directly by altering the land surface water and energy balances1,4. However, at scales of 1001,000 s km, it has been shown that forests can also alter the hydrological cycle through indirect effects on clouds and precipitation caused by land surfaceatmosphere interactions5. This could have profound implications for forest management, spatial planning and local climate change mitigation. Both the process of cloud formation and the indirect impacts of land surface conditions on clouds are still poorly understood, in spite of its central role in the climate system and climate change projections6. As a result, model simulations and projections involving these processes show a wide disparity7.

Direct (thermodynamic) effects of forests on the exchange of water and energy at the land surface are generally well understood. Forests have a lower albedo (that is, they appear darker), which causes them to absorb more of the Suns energy than their surroundings1,4. Forest canopies also provide a rougher surface8, thus promoting an efcient exchange of heat, moisture and momentum between the land surface and the atmosphere, whereas tempering the surface temperature and further increasing the net available energy. The resulting excess energy is either used for evaporation or transpiration of water (together referred to as evapotranspiration), or for heating of the well-mixed atmospheric boundary layer (ABL)9. Indirect biophysical effects of forests are more uncertain. Higher evapotranspiration generally promotes shallow cumulus development10,11, although under certain atmospheric conditions low rather than high soil moisture conditions are known to enhance cloud formation and precipitation10,12. Other studies have also highlighted the importance of sensible heat uxes, frictional convergence and heterogeneity-induced mesoscale circulation for cloud formation1315. In addition, emissions of biogenic volatile organic compounds (BVOCs) by trees promote cloud cover16. The highly reactive BVOCs oxidize rapidly to form secondary organic aerosols17, which can grow through condensation and coagulation to the size of cloud condensation nuclei.

Observational studies disagree on the direction of forest impact on clouds. In eastern Amazonia, local increases in cloud cover have been reported over deforested areas18,19. Contrastingly, summertime clouds were found to form over natural bushland along the bunny fence in semi-arid western Australia but not over adjacent agricultural land20, consistent with higher evapotranspiration and albedo of forest under semi-arid conditions21,22. Studies in the south-eastern and mid-western United States found more clouds over forest and cropforest boundary23,24, suggesting a mesoscale forest-breeze circulation driven by differences in sensible heat uxes. Contrastingly, it was noted that during summer drought in the central United States, shallow cumulus occurred more frequently over lightly vegetated than heavily vegetated landscapes25. For boreal forests, it was shown that their BVOC emission favours cloud formation16. With multiple processes affecting preferred cloud formation, a better understanding of the magnitude and direction of the effect of temperate forest on clouds and climate is needed, in particular in western Europe where many forests are located near densely populated areas.

To exclude confounding effects of topography as a static lifting mechanism that facilitates cloud formation24, we focus our analysis on the largest temperate forests in Europe without pronounced orography (Landes and Sologne) and with sharp forestcropland contrasts in several directions. This allows a study of regional-scale land-use effects in isolation

of confounding orographic effects. Most other large forest regions in Europe are located in hilly or mountainous areas26 where land-use effects cannot be isolated from orographic effects based on observations alone. The forest size (Landes has a forest area of over 12,000 km2) is also large enough for ABL conditions to reect forest surface conditions. Landes and Sologne experience similar climate conditions, with JuneAugust (hereafter JJA) temperatures of 19.3 C and 20.9 C, and JJA precipitation of 150 and 143 mm for Sologne and Landes, respectively, although their species composition differs. In Sologne, the original and dominant tree cover of broadleaf species exists, dominated by oak (Quercus petraea and Quercus robur). The more southern Landes region is a planted maritime pine (Pinus pinaster) forest.

Here we analyse cloud frequency over the Landes and Sologne forest regions based on a decade of high-resolution spatial (down to 1 km) and high-frequency temporal (15 min) observations from the geostationary Meteosat Second Generation (MSG) satellite. We evaluate cloud frequency by the fraction of the time (daylight only, 618 UTC) that clouds are detected within a pixel. To increase the robustness of our results, we use two fully independent cloud detection algorithms (see Methods). The Cloud Physical Properties algorithm (MSG-CPP) uses information from multiple (low-resolution) MSG channels, whereas the High Resolution Visible algorithm (MSG-HRV) only uses the highest resolution visible information. Our analysis reveals a strong increase in cloud cover over large forest regions in western Europe. In addition, we show that widespread windthrow by cyclone Klaus in the Landes forest led to a signicant decrease in local cloud cover in subsequent years, suggesting a long-term impact of climate extremes on forest ecosystems and land surfaceatmosphere interactions. Strong cloud development along the downwind edges of larger forest areas are consistent with a forest-breeze mesoscale circulation. We conclude that forest impact on local climate conditions is more complex than previously thought and can include effects on cloud formation, mesoscale circulation and possibly the initiation of deep convection.

ResultsCloud frequency differences. Both Landes and Sologne represent large forest areas surrounded by crop and grassland (Fig. 1a,b) typical for much of the western European landscape (Supplementary Fig. 1a). In contrast to other forested regions, orography is nearly absent with maximum (gradual) elevation differences in the order of 100200 m over the region (Supplementary Fig. 1bd). For both regions, summertime clouds are found to occur more frequently over forest than over surrounding agricultural land, with the spatial pattern of cloud frequency closely resembling forest cover (Fig. 1cf). The fractional increase in JJA cloud frequency over forest is generally in the range of 0.050.15. We nd similar spatial patterns for the two independent cloud retrieval products (see Methods). Sensitivity analyses on cloud cover estimates (see Methods and Supplementary Figs 25) show that our results are robust over a range of thresholds for cloud detection. Differences in daily JJA cloud frequency between forest and non-forest boxes are also highly signicant (two-sample t-test, Po0.05), but stronger for Landes (P 10 6 and 10 5 for 20042008) than for Sologne

(P 0.01 and 0.02 over the same period). The non-forested

boxes do not signicantly differ (P 0.54 for Landes and P 0.88

for Sologne), indicating that the local forest-induced changes in cloud frequency are independent of regional-scale gradients in cloud climatology. The presence of a strong northsouth gradient in cloud cover for Sologne shows that local land-use

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Figure 1 | Forest cover and summer cloud occurrence. (a,b) Land cover maps for the Landes (a) and Sologne (b) regions. (cf) Mean JJA cloud frequency (20042008, 618 UTC) for the physics-based MSG-CPP product (c,d) and the empirical MSG-HRV product (e,f). (g,h) MSG channel 12 snapshots for17 July 2006, 13 UTC (g) and 1 May 2012, 15 UTC (h). Black squares indicate forest (thick line) and non-forest (thin line) focus regions for visual reference and analysis in Fig. 2.

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Figure 2 | Temporal and spatial patterns of preferred cloud occurrence over forest. Seasonal (a) and diurnal (b) evolution of mean JJA (indicated by box in a) difference in cloud frequency for Sologne region. (c) Impact of regional (10 m) meridional wind component on JJA cloud frequency for Landes. (d) Average July LST (20022014) from MODIS Aqua for Sologne. In a,b, thick (thin) vertical lines indicate 50 (95) percentile intervals obtained from bootstrapping for the forest (green) and non-forest boxes (orange) in Fig. 1. Shading indicates periods of signicant difference at the 95% condence level. In c, contours represent 90th percentiles to account for differences in mean cloud frequency with wind conditions. It is noteworthy that positive meridional wind is wind blowing from south to north. Cloud frequency is based on the MSG-CPP product. See also Supplementary Fig. 17.

effects are superimposed on larger-scale weather patterns and potentially also patterns in soil moisture availability at shorter timescales27. Although the climatology averages over all synoptic conditions including days with full (or absence of) cloud cover, example snapshots (Fig. 1g,h) and animations (Supplementary Movies 14 and Supplementary Figs 69) based on high-resolution imagery reveal that conditions exist in which clouds occur only over forest. In isolated cases, this can even develop into preferred triggering of deep convection(17 July 2006 case).

Temporal dynamics. Figure 2 explores some key temporal and spatial aspects of the contrast in cloud frequency. Figure 2a reveals the existence of a seasonal switch in cloud preference for Sologne. During JJA, there is a signicant preference for clouds to occur over the forest, whereas outside of this period differences in cloud frequency are not signicant. We use the Enhanced Vegetation Index (EVI) to investigate possible links with the seasonal development of vegetation in both regions. In comparison with the widely used Normalized Difference Vegetation Index, the EVI is more sensitive to biomass and canopy structure. In Sologne, EVI is initially higher over the surrounding non-forest areas (that is, forest surroundings greener than forest; Supplementary Fig. 10) but decreasing strongly during summer due to harvesting, leading to a strong surface

warming (Supplementary Fig. 11). For Landes, these seasonal dynamics are less pronounced. Here, the spatial EVI contrast is generally smaller, and both higher and lower EVI values can be found in the surrounding areas during late summer, suggesting that canopy structural differences alone are not a main determinant of the observed differences in cloud frequency. There are pronounced and signicant difference in the diurnal cycles of JJA cloud cover over forest and non-forest (Fig. 2b and Supplementary Figs 12 and 13). Over forests, clouds develop earlier and faster than over the surrounding land (peak around 08:00 h UTC), while persisting longer into the evening (peak difference 15:0016:00 h UTC). This probably reects an earlier onset and longer duration of the thermal activity and moistening11 of the ABL over forests. There is no signicant difference between 11 and 13 UTC, probably reecting the fact that clouds have developed fully over both forest and surrounding areas.

Impact of synoptic conditions. We test for the presence of forest-breeze mesoscale circulations15 by classifying all days by (meridional) wind speed (Fig. 2c and Supplementary Fig. 14c) and wind direction (Supplementary Figs 15 and 16). This analysis reveals that the spatial pattern in cloud occurrence at the larger Landes forest is strongly impacted by wind conditions. We nd a consistent pattern of higher cloud frequency at the

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Figure 3 | Impact of cyclone Klaus on Landes. (a) Percentage of windthrow following the passage of Klaus on 24 January 2009 (data: IGN).(b) Changes in seasonal dynamics of differences in cloud frequency (blue line) associated with Klaus (red vertical line) based on MSG-CPP and calculated as the average over forest (thick box in a covering area with maximum windthrow) minus the average over non-forest areas (two thin boxes in (a). Ten-day average differences were tted with a squared sine with trend (thick black line). Shading indicates 95% condence bounds for the t.

downwind (and to a lesser extent, cross-wind) edge of the forest over all wind directions. This edge effect is most pronounced at higher regional average wind speeds (41 m s 1). These patterns are consistent with a forest-breeze circulation driven by locally enhanced heating over the forest1,4, as previously observed for Landes8. In calm conditions, convergence over the forest favours cloud development. Under moderate winds, the thermally induced surface pressure gradient weakens at the upwind edge, due to advection of cool air into the forest. By contrast at the downwind edge, the local forest breeze opposes the synoptic ow, enhancing convergence and providing favourable conditions for convection. No clear relation between patterns of cloud frequency and regional wind conditions was found for the smaller Sologne forest (Supplementary Figs 14 and 16) where edge effects are more difcult to detect. We also did not nd a strong dependence between synoptic conditions (measured by sea level pressure) and difference in cloud frequency (Supplementary Fig. 17), suggesting that differences in cloud cover between forest and surrounding areas occur under a range of synoptic conditions possibly involving different dominant mechanisms. The thermally induced forest breeze is likely to be strongest in June and July. Analysis of land surface temperature (LST) observations (Fig. 2d and Supplementary Fig. 11) reveals a progressive increase in LST over the surrounding areas during the summer season. The stable LST over forest probably reects sustained evapotranspiration rates throughout the summer season, whereas the strong increase in LST over surrounding areas (up to 10 K for Sologne) is indicative for declining evaporation rates. The associated increase in thermal convection will counteract the increased thermal convection over forest due to the lower albedo.

Impact of cyclone Klaus. On 24 January 2009, cyclone Klaus made landfall over southern France with a core pressure reaching as low as 965 hPa and storm gusts of up to 55 ms 1 recorded at low-level stations13, leading to extensive damage across southern France and the northern Iberian Peninsula. The Landes forest was hit particularly severely. Many stands experienced extensive damage (Fig. 3a) by windthrow or windsnap (that is, trees uprooted or broken by wind), leading to an estimated 45 Mt of CO2 emission28. Owing to the spatial

extent and near-instantaneous occurrence of the damage, Klaus provides a unique possibility to investigate the effects of sudden forest removal on cloud frequency. Large changes in JJA cloud frequency occurred over the region that suffered most damage (Fig. 3b and Supplementary Fig. 3). In the 5-year period, 20092013 following Klaus, local changes in cloud frequency up to 0.20 were found with respect to the period 20042008

(P 0.001 over the forest box in Fig. 3a), whereas no signicant

changes were found for boxes outside the storm-affected area (P 0.42 and P 0.58) nor for Sologne (P 0.63). The

timing of the sudden change is also consistent with the passing of Klaus. Before 2009, the difference shows a marked seasonal cycle peaking in summer with an amplitude of 0.114 (0.0930.135, 95% condence), reducing by almost an order of magnitude to 0.020 (0.0020.038) after Klaus. The recovery time of these forests, at least when it comes to their impact on cloud formation, is thus well over 5 years and possibly much longer.

DiscussionBased on the results, we provide a conceptual model for temperate forest impact on clouds (Fig. 4). Differences in the surface energy balance probably affect cloud occurrence, as several studies have shown that changes in convection due to changes in the land surface energy balance alone can create differences in cloud cover10,11. Our results do not contradict the important role of albedo that was hypothesized in earlier studies21. Albedo values for the Sologne and Landes forests are typically in the range of 0.110.14, whereas the surrounding areas are more reective with albedo values in the range of 0.160.19 (Supplementary Fig. 18). Such differences are large enough to impact the growth and properties of the ABL. Differences in the partitioning of available energy also drive ABL dynamics and the timing of the onset of shallow cumulus formation11, but they might be of less importance than albedo differences9. Nonetheless, our results are consistent with observed higher sensible heat uxes over temperate forest4, leading to a growing ABL and a forest breeze. We can reconcile our results with studies over Amazonia18,19 by recognizing that in both cases higher sensible heat uxes trigger preferred cloud formation4,23. Although this may seemingly contradict the cooler LSTs over forest, differences in roughness prevent LST from being a direct measure of sensible heat ux and temperature-sensitive

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Figure 4 | Possible pathways of temperate forest impact on convective cloud formation. Background shading indicates potential temperate (blue cooler, red warmer). Arrows indicate radiative (orange), heating

(red), moistening (blue), mechanical (light blue) and biogeochemical (green) processes. Over forest, less reection of incoming solar radiation leads to larger turbulent exchange and thermal convection, increasing both the lifting condensation level and ABL height. This process is amplied by frictional convergence and the development of a forest breeze, and possibly the release of BVOCs.

ux partitioning over forest4,9 might not be independent of cloud cover conditions. It should be noted that both a lifting mechanism (provided by sensible heat ux) and sufcient moisture (provided by latent heat ux) are required for development of convective clouds. Owing to the higher net radiation provided by the albedo effect and increased roughness, temperate forests can have higher sensible as well as latent heat uxes1,4.

Aerodynamic roughness has also been identied as an important factor in controlling not only the surface energy balance and mixed layer conditions29,30, but also leading to enhanced turbulence, frictional convergence due to slowing air masses, edge effects and/or mesoscale circulation10,14. The strong effect of wind conditions on patterns of cloud enhancement suggest the development of mesoscale circulations8 (forest breeze) superimposed on background wind, possibly affected by changing combinations of land surface energy balance differences and roughness. Although the existence of a forest breeze and its contribution to differences in cloud conditions has been conrmed by dedicated small-scale experiments in Landes in the framework of HAPEX-Mobilhy8, the contribution of these effects at the regional scale remains to be tested. In addition to thermodynamic processes, the large fetch and residence time (Bhours) is also favourable for the formation of secondary organic aerosols, driven by the larger BVOC emission rate of trees at the Sologne and Landes forests. Increased cloud condensation nuclei concentrations in the downwind direction could also contribute to the observed effect of wind conditions on patterns of cloud enhancement31. In reality, there is likely to be a complex interplay of the physical and biogeochemical processes depicted in Fig. 4, whereby the relative contribution of each process will depend on synoptic conditions, vegetation seasonality and soil moisture. Quantifying these dynamic contributions and their interplay should be a priority area for future research.

Our ndings have important implications for the evaluation of water and climate services provided by temperate forests in

Europe21,32. The increase in cloud cover has the potential to locally offset the warming effect due to lower albedo16 and can lead to larger light and water use efciency in forest ecosystems21. Our results also highlight the need to include indirect water cycle impacts when evaluating the impact of climate extremes such as cyclone Klaus on biogeochemical cycles and energy exchange28,33. Anecdotal evidence shows that forests can even act as a source region for deep convection, thereby possibly intensifying the hydrological cycle over land. Our study also contributes to an ongoing debate on the importance of land surface heterogeneity, either by land use or soil moisture, on clouds and precipitation15,27,34. Although our study focused on forests in absence of topography, we believe the mechanisms behind cloud cover enhancement will also play a role in the presence of a static lifting mechanism. However, as forest cover correlates spatially with topography26, disentangling these effects can no longer be done based on observations alone and will require a systematic modelling approach. Future research will have to learn whether convective cloud preference over forests is also associated with triggering of deep convection and increased rainfall. Possibly, the preference for clouds to form over forest can one day be exploited, to mitigate the local impacts of a warmer climate, in particular near urban areas.

Methods

Data sets. The primary data in this study are based on measurements fromthe Spinning Enhanced Visible and InfraRed Imager (SEVIRI) on board the MSG series of satellites. Ten years of data were used for the period 20042013at a 15 min resolution, consisting of over 350,000 images in total. For mostof the analysis we focused on the daytime (618 UTC) hours of the summer season (JJA), reducing the number of images to 10 92 48 44,160 per region.

Data of 10 m wind speed were obtained from ERA-Interim. Moderate Resolution Imaging Spectroradiometer (MODIS) albedo and EVI products were obtained from lpdaac.usgs.gov. MODIS LST data were taken from a recent global analysis of LST dynamics35. The storm damage map for Klaus was provided by Inventaire Forestier National (available from http://inventaire-forestier.ign.fr/cartoklaus/carto/afficherCarto

Web End =http://inventaire-forestier.ign.fr/ http://inventaire-forestier.ign.fr/cartoklaus/carto/afficherCarto

Web End =cartoklaus/carto/afcherCarto , version 2009). Land-use maps for 2010 were taken from HILDA3638 (available from http://www.wageningenur.nl/hilda

Web End =www.wageningenur.nl/hilda ).

CPP algorithm. We used SEVIRI-based cloud products generated with the MSG-CPP algorithm at KNMI and available via http://data.knmi.nl

Web End =http://data.knmi.nl . To avoid false detection, we only identied clouds when the cloud optical thickness exceeds 0.3. The algorithm rst identies cloudy pixels using a series of threshold and spatial coherence tests on the measured visible/near-infrared reectances and infrared brightness temperatures39. In a second step, cloud optical properties (optical thickness and particle size) were retrieved by matching satellite observed reectances at visible (0.6 mm) and near-infrared(1.6 mm) wavelengths to simulated reectances of homogeneous clouds composed of either liquid or ice particles. The thermodynamic phase (liquid or ice) is determined as part of this procedure, using a cloud-top temperature estimate as additional input40,41. MSG-SEVIRI shortwave channels were calibrated with MODIS measurements42.

HRV algorithm. A second empirical cloud product (MSG-HRV) was derived independently using the SEVIRI HRV broadband channel (0.41.1 mm). Cloud cover was identied when radiation measurements (at B1 km pixel scale) exceeded the climatological radiation in the absence of clouds for that pixel by a constant threshold (ten counts). The clear-sky climatology was constructed by identifying the steepest section in the empirical cumulative distribution functions of all the measurements over 10 years for every hour of the day and for every 10-day period in the year (400 values in total). We found that this procedure produces patterns of clear-sky radiation which agree well with MODIS albedo maps (Supplementary Fig. 18).

Code availability. The codes used for analysis and production of the MSG-HRV cloud product are available from the corresponding author on reasonable request.

Data availability. The data sets generated during and/or analysed during the current study are available from the corresponding author on reasonable request.

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Acknowledgements

We thank Barry Gardiner (INRA) and colleagues for their help with the Klaus storm

data. D.G.M. acknowledges nancial support from The Netherlands Organization for

Scientic Research through grant 863.14.004. G.-J.N. acknowledges support from the

H2020 PEGASUS project with grant agreement 633814.

Author contributions

A.J.T. designed the study and carried out the analyses. J.F.M. provided the MSG-CPP

data and helped initiating the study. C.M.T. provided the MSG-HRV and Aqua LST data

and helped with the analysis. C.M.T., R.V., L.A.M. and D.G.M. provided additional

analysis. All authors contributed to the writing and the interpretation of the results.

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How to cite this article: Teuling, A. J. et al. Observational evidence for cloud

cover enhancement over western European forests. Nat. Commun. 8, 14065

doi: 10.1038/ncomms14065 (2017).

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