Abstract
The frequency and intensity of droughts have increased over the decades, leading to increased forest decline. The response of forest to drought can be evaluated by both its sensitivity to drought (resistance) and its post-drought recovery rate (resilience). However, it remains uncertain how drought resistance and resilience of forests change over time under climate change. We assessed the spatiotemporal dynamics of forest resistance and resilience to drought over the past century (1901–2015) with global tree ring data records from 2,935 sites, in conjunction with plant trait data. We found that gymnosperms and angiosperms showed different spatial patterns of drought resistance and resilience, driven by variations in eco-physiological traits. Resistance and resilience also varied with drought seasonal timing. Surprisingly, we found that the trade-off between resistance and resilience for gymnosperms, previously reported only spatially, also occurred at the temporal scale. In particular, drought resilience markedly increased, but resistance decreased, for gymnosperms between 1950–1969 and 1990–2009, indicating that previous model simulations assuming invariant resistance may have underestimated the impacts of drought on gymnosperm-dominated forests under future climate change.
This is a preview of subscription content, access via your institution
Access options
Access Nature and 54 other Nature Portfolio journals
Get Nature+, our best-value online-access subscription
$29.99 / 30 days
cancel any time
Subscribe to this journal
Receive 12 digital issues and online access to articles
$119.00 per year
only $9.92 per issue
Buy this article
- Purchase on Springer Link
- Instant access to full article PDF
Prices may be subject to local taxes which are calculated during checkout
Similar content being viewed by others
Data availability
All data from public sources used in this study can be obtained from https://figshare.com/articles/Trade-off_between_gymnosperm_resistance_and_resilience_increases_forest_sensitivity_to_extreme_drought/12047241.
Code availability
Computer codes for the analysis of the data are available from https://github.com/LilyXiangyi/ForestResponse.
References
IPCC Climate Change 2013: The Physical Science Basis (eds Stocker, T. F. et al.) (Cambridge Univ. Press, 2013).
Trenberth, K. E. et al. Global warming and changes in drought. Nat. Clim. Change 4, 17–22 (2014).
Allen, C. D. et al. A global overview of drought and heat-induced tree mortality reveals emerging climate change risks for forests. For. Ecol. Manage. 259, 660–684 (2010).
Anderegg, W. R. L. et al. The roles of hydraulic and carbon stress in a widespread climate-induced forest die-off. Proc. Natl Acad. Sci. USA 109, 233–237 (2012).
Anderegg, W. R. L. et al. Pervasive drought legacies in forest ecosystems and their implications for carbon cycle models. Science 349, 528–532 (2015).
Charney, N. D. et al. Observed forest sensitivity to climate implies large changes in 21st century North American forest growth. Ecol. Lett. 19, 1119–1128 (2016).
Carnicer, J. et al. Regime shifts of Mediterranean forest carbon uptake and reduced resilience driven by multidecadal ocean surface temperatures. Glob. Change Biol. 25, 2825–2840 (2019).
McDowell, N. et al. Mechanisms of plant survival and mortality during drought: why do some plants survive while others succumb to drought? New Phytol. 178, 719–739 (2008).
Gazol, A. et al. Forest resilience to drought varies across biomes. Glob. Change Biol. 24, 2143–2158 (2018).
Huang, M., Wang, X., Keenan, T. F. & Piao, S. Drought timing influences the legacy of tree growth recovery. Glob. Change Biol. 24, 3546–3559 (2018).
García-Palacios, P., Gross, N., Gaitán, J. & Maestre, F. T. Climate mediates the biodiversity–ecosystem stability relationship globally. Proc. Natl Acad. Sci. USA 115, 8400–8405 (2018).
Tei, S. et al. Tree-ring analysis and modeling approaches yield contrary response of circumboreal forest productivity to climate change. Glob. Change Biol. 23, 5179–5188 (2017).
Jiang, P. et al. Enhanced growth after extreme wetness compensates for post-drought carbon loss in dry forests. Nat. Commun. 10, 195 (2019).
Gedalof, Z. & Berg, A. A. Tree ring evidence for limited direct CO2 fertilization of forests over the 20th century. Glob. Biogeochem. Cycles 24, GB3027 (2010).
Peñuelas, J., Canadell, J. G. & Ogaya, R. Increased water-use efficiency during the 20th century did not translate into enhanced tree growth. Glob. Ecol. Biogeogr. 20, 597–608 (2011).
Swann, A. L. S., Hoffman, F. M., Koven, C. D. & Randerson, J. T. Plant responses to increasing CO2 reduce estimates of climate impacts on drought severity. Proc. Natl Acad. Sci. USA 113, 10019–10024 (2016).
Liu, Y. et al. Increasing atmospheric humidity and CO2 concentration alleviate forest mortality risk. Proc. Natl Acad. Sci. USA 114, 9918–9923 (2017).
Kattge, J. et al. TRY – a global database of plant traits. Glob. Change Biol. 17, 2905–2935 (2011).
van Bodegom, P. M., Douma, J. C. & Verheijen, L. M. A fully traits-based approach to modeling global vegetation distribution. Proc. Natl Acad. Sci. USA 111, 13733–13738 (2014).
Warren, J. M., Norby, R. J., Wullschleger, S. D. & Oren, R. Elevated CO2 enhances leaf senescence during extreme drought in a temperate forest. Tree Physiol. 31, 117–130 (2011).
Ogasa, M., Miki, N. H., Murakami, Y. & Yoshikawa, K. Recovery performance in xylem hydraulic conductivity is correlated with cavitation resistance for temperate deciduous tree species. Tree Physiol. 33, 335–344 (2013).
Martin-StPaul, N., Delzon, S. & Cochard, H. Plant resistance to drought depends on timely stomatal closure. Ecol. Lett. 20, 1437–1447 (2017).
Matheny, A. M., Mirfenderesgi, G. & Bohrer, G. Trait-based representation of hydrological functional properties of plants in weather and ecosystem models. Plant Divers. 39, 1–12 (2017).
Hartmann, H. et al. Research frontiers for improving our understanding of drought-induced tree and forest mortality. New Phytol. 218, 15–28 (2018).
Anderegg, W. R. L. et al. Hydraulic diversity of forests regulates ecosystem resilience during drought. Nature 561, 538 (2018).
Babst, F. et al. A tree-ring perspective on the terrestrial carbon cycle. Oecologia 176, 307–322 (2014).
Wu, X. et al. Differentiating drought legacy effects on vegetation growth over the temperate Northern Hemisphere. Glob. Change Biol. 24, 504–516 (2018).
Isbell, F. et al. Biodiversity increases the resistance of ecosystem productivity to climate extremes. Nature 526, 574–577 (2015).
Johnson, D. M., Mcculloh, K. A., Woodruff, D. R. & Meinzer, F. C. Plant science hydraulic safety margins and embolism reversal in stems and leaves: why are conifers and angiosperms so different? Plant Sci. 195, 48–53 (2012).
Choat, B. et al. Global convergence in the vulnerability of forests to drought. Nature 491, 752–755 (2012).
Carnicer, J., Barbeta, A., Sperlich, D., Coll, M. & Peñuelas, J. Contrasting trait syndromes in angiosperms and conifers are associated with different responses of tree growth to temperature on a large scale. Front. Plant Sci. 4, 409 (2013).
Gazol, A., Camarero, J. J., Anderegg, W. R. L. & Vicente-Serrano, S. M. Impacts of droughts on the growth resilience of Northern Hemisphere forests. Glob. Ecol. Biogeogr. 26, 166–176 (2017).
D’Orangeville, L. et al. Drought timing and local climate determine the sensitivity of eastern temperate forests to drought. Glob. Change Biol. 24, 2339–2351 (2018).
Elith, J., Leathwick, J. R. & Hastie, T. A working guide to boosted regression trees. J. Anim. Ecol. 77, 802–813 (2008).
Butler, E. E. et al. Mapping local and global variability in plant trait distributions. Proc. Natl Acad. Sci. USA 114, E10937–E10946 (2017).
Markesteijn, L., Poorter, L., Paz, H., Sack, L. & Bongers, F. Ecological differentiation in xylem cavitation resistance is associated with stem and leaf structural traits. Plant Cell Environ. 34, 137–148 (2011).
Greenwood, S. et al. Tree mortality across biomes is promoted by drought intensity, lower wood density and higher specific leaf area. Ecol. Lett. 20, 539–553 (2017).
Meinzer, F. C. et al. Maximum height in a conifer is associated with conflicting requirements for xylem design. Proc. Natl Acad. Sci. USA 105, 12069–12074 (2008).
Giardina, F. et al. Tall Amazonian forests are less sensitive to precipitation variability. Nat. Geosci. 11, 405–409 (2018).
Brodribb, T. J., McAdam, S. A. M., Jordan, G. J. & Martins, S. C. V. Conifer species adapt to low-rainfall climates by following one of two divergent pathways. Proc. Natl Acad. Sci. USA 111, 14489–14493 (2014).
Duan, H. et al. Drought responses of two gymnosperm species with contrasting stomatal regulation strategies under elevated [CO2] and temperature. Tree Physiol. 35, 756–770 (2015).
Firn, J. et al. Leaf nutrients, not specific leaf area, are consistent indicators of elevated nutrient inputs. Nat. Ecol. Evol. 3, 400–406 (2019).
Konings, A. G. & Gentine, P. Global variations in ecosystem-scale isohydricity. Glob. Change Biol. 23, 891–905 (2017).
Yin, J. & Bauerle, T. L. A global analysis of plant recovery performance from water stress. Oikos 126, 1377–1388 (2017).
Anderegg, W. R. L. et al. Woody plants optimise stomatal behaviour relative to hydraulic risk. Ecol. Lett. 21, 968–977 (2018).
Gessler, A., Schaub, M. & McDowell, N. G. The role of nutrients in drought-induced tree mortality and recovery. New Phytol. 214, 513–520 (2017).
Trugman, A. T. et al. Tree carbon allocation explains forest drought-kill and recovery patterns. Ecol. Lett. 21, 1552–1560 (2018).
Sohn, J. A., Saha, S. & Bauhus, J. Potential of forest thinning to mitigate drought stress: a meta-analysis. For. Ecol. Manage. 380, 261–273 (2016).
Trouvé, R., Bontemps, J. D., Collet, C., Seynave, I. & Lebourgeois, F. Radial growth resilience of sessile oak after drought is affected by site water status, stand density, and social status. Trees 31, 517–529 (2017).
Le Quéré, C. et al. Global Carbon Budget 2018. Earth Syst. Sci. Data 10, 2141–2194 (2018).
Franks, P. J. et al. Sensitivity of plants to changing atmospheric CO2 concentration: from the geological past to the next century. New Phytol. 197, 1077–1094 (2013).
Keenan, T. F. et al. Increase in forest water-use efficiency as atmospheric carbon dioxide concentrations rise. Nature 499, 324–327 (2013).
Frank, D. C. et al. Water-use efficiency and transpiration across European forests during the Anthropocene. Nat. Clim. Change 5, 579–583 (2015).
Drake, B. L., Hanson, D. T., Lowrey, T. K. & Sharp, Z. D. The carbon fertilization effect over a century of anthropogenic CO2 emissions: higher intracellular CO2 and more drought resistance among invasive and native grass species contrasts with increased water use efficiency for woody plants in the US Southwest. Glob. Change Biol. 23, 782–792 (2017).
Schwalm, C. R. et al. Global patterns of drought recovery. Nature 548, 202–205 (2017).
Niinemets, Ü., Flexas, J. & Peñuelas, J. Evergreens favored by higher responsiveness to increased CO2. Trends Ecol. Evol. 26, 136–142 (2011).
Tor-ngern, P. et al. Increases in atmospheric CO2 have little influence on transpiration of a temperate forest canopy. New Phytol 205, 518–525 (2015).
Voelker, S. L. et al. A dynamic leaf gas‐exchange strategy is conserved in woody plants under changing ambient CO2: evidence from carbon isotope discrimination in paleo and CO2 enrichment studies. Glob. Change Biol. 22, 889–902 (2016).
Domec, J.-C. et al. Acclimation of leaf hydraulic conductance and stomatal conductance of Pinus taeda (loblolly pine) to long-term growth in elevated CO2 (free-air CO2 enrichment) and N-fertilization. Plant Cell Environ. 32, 1500–1512 (2009).
Domec, J.-C., Schafer, K., Oren, R., Kim, H. S. & McCarthy, H. R. Variable conductivity and embolism in roots and branches of four contrasting tree species and their impacts on whole-plant hydraulic performance under future atmospheric CO2 concentration. Tree Physiol. 30, 1001–1015 (2010).
Domec, J. C., Smith, D. D. & McCulloh, K. A. A synthesis of the effects of atmospheric carbon dioxide enrichment on plant hydraulics: implications for whole‐plant water use efficiency and resistance to drought. Plant Cell Environ. 40, 921–937 (2017).
McDowell, N. G. Mechanisms linking drought, hydraulics, carbon metabolism, and vegetation mortality. Plant Physiol. 155, 1051–1059 (2011).
McDowell, N. G. et al. Evaluating theories of drought-induced vegetation mortality using a multimodel-experiment framework. New Phytol. 200, 304–321 (2013).
Mitchell, P. J., O’Grady, A. P., Hayes, K. R. & Pinkard, E. A. Exposure of trees to drought-induced die-off is defined by a common climatic threshold across different vegetation types. Ecol. Evol. 4, 1088–1101 (2014).
Choat, B. et al. Triggers of tree mortality under drought drought and forest mortality. Nature 558, 531–539 (2018).
Andreu-Hayles, L. et al. Long tree-ring chronologies reveal 20th century increases in water-use efficiency but no enhancement of tree growth at five Iberian pine forests. Glob. Change Biol. 17, 2095–2112 (2011).
Girardin, M. P., Bouriaud, O., Hogg, E. H., Kurz, W. & Zimmermann, N. E. No growth stimulation of Canada’s boreal forest under half-century of combined warming and CO2 fertilization. Proc. Natl Acad. Sci. USA 113, E8406–E8414 (2016).
Zhao, S. et al. The International Tree-Ring Data Bank (ITRDB) revisited: data availability and global ecological representativity. J. Biogeogr. 46, 355–368 (2019).
Gao, S. et al. Dynamic responses of tree-ring growth to multiple dimensions of drought. Glob. Change Biol. 24, 5380–5390 (2018).
Engelbrecht, B. M. J. et al. Drought sensitivity shapes species distribution patterns in tropical forests. Nature 447, 80–83 (2007).
Babst, F. et al. Twentieth century redistribution in climatic drivers of global tree growth. Sci. Adv. 5, eaat4313 (2019).
Ciemer, C. et al. Higher resilience to climatic disturbances in tropical vegetation exposed to more variable rainfall. Nat. Geosci. 12, 174–179 (2019).
Bunn, A. G. A dendrochronology program library in R (dplR). Dendrochronologia 26, 115–124 (2008).
Cook, E. R. & Kairiukstis, L. A. Methods of Dendrochronology: Applications in the Environmental Sciences (Springer Science & Business Media, 2013).
Harris, I., Jones, P. D., Osborn, T. J. & Lister, D. H. Updated high-resolution grids of monthly climatic observations—the CRU TS3.10 Dataset. Int. J. Climatol. 34, 623–642 (2014).
Beguería, S., Vicente-Serrano, S. M., Reig, F. & Latorre, B. Standardized precipitation evapotranspiration index (SPEI) revisited: parameter fitting, evapotranspiration models, tools, datasets and drought monitoring. Int. J. Climatol. 34, 3001–3023 (2014).
Wieder, W. R., Boehnert, J., Bonan, G. B. & Langseth, M. Regridded harmonized world soil database v1.2. http://daac.ornl.gov (Oak Ridge National Laboratory Distributed Active Archive Center, 2014).
Crowther, T. W. et al. Mapping tree density at a global scale. Nature 525, 201–205 (2015).
Simard, M., Pinto, N., Fisher, J. B. & Baccini, A. Mapping forest canopy height globally with spaceborne lidar. J. Geophys. Res. 116, G04021 (2011).
Zanne, A. E. et al. Global wood density database. Dryad https://doi.org/10.5061/dryad.234/1 (2009).
Chave, J. et al. Towards a worldwide wood economics spectrum. Ecol. Lett. 12, 351–366 (2009).
Ridgeway, G. Generalized Boosted Models: A guide to the gbm package. R version 2.1.5. https://cran.r-project.org/web/packages/gbm/index.html (2007).
Fang, O. & Zhang, Q. B. Tree resilience to drought increases in the Tibetan Plateau. Glob. Change Biol. 25, 245–253 (2019).
Brienen, R. J. W. et al. Long-term decline of the Amazon carbon sink. Nature 519, 344–348 (2015).
Brienen, R. J. W. et al. Plot Data from: Long-term Decline of the Amazon Carbon Sink https://doi.org/10.5521/ForestPlots.net/2014_4 (Forest Plots, 2014).
Acknowledgements
This study was supported by the National Natural Science Foundation of China (nos. 41530528 and 41988101) and the Second Tibetan Plateau Scientific Expedition and Research Program (no. 2019QZKK0208). P.C. and J.P. acknowledge support from European Research Council Synergy project SyG-2013-610028 IMBALANCE-P and P.C. acknowledges support from the ANR CLAND Convergence Institute. We gratefully acknowledge all voluntary researchers who have contributed to and maintained the ITRDB. We also thank A. K. Post for proofreading the article.
Author information
Authors and Affiliations
Contributions
S.P. designed the research. X.L. performed analysis and created all the figures. X.L. and S.P. drafted the paper. All authors contributed to interpretation of the results and to the text.
Corresponding author
Ethics declarations
Competing interests
The authors declare no competing interests.
Additional information
Publisher’s note Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Extended data
Extended Data Fig. 1 Examples for identifying season categories.
(a) Location of the ring-width index (RWI) at four sites, co551 (40.05°N, 105.43°W), chin048 (30.30°N, 91.52°E), zimb001 (18.67°S, 26.68°E), and ausl004 (32.00°S, 115.65°E). The variation of monthly precipitation minus potential evapotranspiration (P-PET) anomalies divided each drought year into a dry season and a wet season (see details of identification of season categories in Methods) for RWI sites (b) co551 in North America with an elevation of 2560m, (c) chin048 in Asia (elevation missing), (d) zimb001 in Africa with an elevation of 1085m, and (e) ausl004 in Australia with an elevation of 328m. The shaded areas in (b-e) indicate the dry season. The names of the four RWI sites are taken from the ITRDB tree-ring database.
Extended Data Fig. 2 Examples for identifying drought classification for a drought year using RWI site co551.
The drought threshold in (a) the dry season (ThresholdDS) and (b) the wet season (ThresholdWS), derived from the tenth percentile of the data distribution (see details of drought classification in Methods). c, 1966, a DS drought year with a drought only in the dry season, indicated by a mean SPEI in the dry season lower than the drought threshold in the dry season (SPEIDS < ThresholdDS) but a mean SPEI in the wet season higher than the drought threshold in the wet season (SPEIWS > ThresholdWS). d, 1981, a WS drought year with a drought only in the wet season, indicated by SPEIDS > ThresholdDS but SPEIWS < ThresholdWS. e, 1977, a DS+WS drought year with a drought in both the dry and wet seasons, indicated by SPEIDS < ThresholdDS and SPEIWS < ThresholdWS.
Extended Data Fig. 3 Mean resistance and resilience of gymnosperms and angiosperms in drought years.
a, resistance to drought in the dry season (DS droughts), (b) resilience to drought in the dry season (DS droughts), (c) resistance to drought in the wet season (WS droughts), (d) resilience to drought in the wet season (WS droughts). Circles represent the gymnosperm tree-ring sites, and triangles represent the angiosperm tree-ring sites. The color bars denote the range of magnitude of (a, c) mean resistance (Rt) and (b, d) mean resilience (Rs), respectively.
Extended Data Fig. 4 Comparison of ln-transformed resistance (ln(Rt)) and resilience (ln(Rs)) for drought years in both the dry and wet seasons (DS+WS drought), the dry season (DS drought), and the wet season (WS drought) for gymnosperms and angiosperms.
For each row, different letters within a row represent significant differences (p < 0.05) among the drought timings. Values shown in the table are all unitless.
Extended Data Fig. 5 Drought severity (indicated by SPEI) of WS, DS and DS+WS droughts at gymnosperm and angiosperm tree-ring sites.
Significant differences (p < 0.05) among the drought timings were identified by an analysis of variance (one-way ANOVA) and are marked by different letters for gymnosperms (denoted by filled boxplots) and for angiosperms (denoted by open boxplots). The boxes indicate the 25th and 75th percentiles, and the lines in the boxes indicate the medians.
Extended Data Fig. 6 Temporal changes of resistance and resilience for gymnosperm and angiosperm forests during 1910-2009.
Temporal change of (a) gymnosperm resistance, (b) angiosperm resistance, (c) gymnosperm resilience, (d) angiosperm resilience. 290 gymnosperm sites in (a) and (c) and 65 angiosperm sites in (b) and (d) experiencing droughts in all four periods, i.e. before 1950, 1950-1969, 1970-1989, and 1990-2009 were used for temporal analysis. The x-axis represents the range of ln-transformed resistance (ln(Rt + 1)) and resilience (ln(Rs + 1)) at each RWI site during three periods. Histograms (left y-axis) show the distribution of ln (Rt + 1) and ln(Rs + 1) and lines (right y-axis) show the kernel density distribution of ln(Rt + 1) and ln(Rs + 1) during the period of before 1950 (gray), 1950-1969 (blue), 1970-1989 (orange), and 1990-2009 (purple). The boxplots in the inset of each panel show the distribution of temporal change in 1970-1989 (orange) and 1990-2009 (purple) relative to 1950-1969 for all sites. The yellow lines represent median values and points represent mean values in the boxes. The percentages of sites showing positive change (+) and negative change (-) are displayed in the panels. Significant differences (p < 0.05) of all sites between 1970-1989 and 1950-1969, and between 1990-2009 and 1950-1969 were identified by Kruskal-Wallis test and denoted by asterisks (*).
Extended Data Fig. 7 Comparison of hydraulic safety margin (HSM) and specific leaf area (SLA) between gymnosperms and angiosperms.
a, Empirical cumulative distribution function (CDF) of HSM between gymnosperms (black) and angiosperms (blue). b, Empirical CDF of SLA between gymnosperms and angiosperms.
Extended Data Fig. 8 Spatial correlations of differences in resistance and resilience with differences in tree growth, temperature, precipitation, and drought severity between two consecutive periods.
a, Correlations between resistance and RWI (upper panel), and between resilience and RWI (lower panel) across gymnosperm (blue bars) and angiosperm (orange bars) forest sites. b, Correlations between resistance and drought severity (upper panel) and between resilience and drought severity (lower panel) across gymnosperm and angiosperm forest sites. c, Correlations between resistance and temperature (upper panel) and between resilience and temperature (lower panel) across gymnosperm and angiosperm forest sites. d, Correlations between resistance and precipitation (upper panel) and between resilience and precipitation (lower panel) across gymnosperm and angiosperm forest sites. I, differences between 1950-1969 and 1970-1989; II, differences between 1970-1989 and 1990-2009. Significance correlations are denoted by *** (p < 0.001), ** (p < 0.01), and * (p < 0.05).
Extended Data Fig. 9 An example of decrease in drought resistance with increase in drought severity.
A tree-ring site (32.43°N, 110.79°W, Ponderosa pine) in Arizona, USA presents a decrease in drought resistance with increase in drought severity during three periods (i.e. 1950-1969, 1970-1989, and 1990-2009). The name of the tree-ring site is az598 in the ITRDB tree-ring database. Blue bars (upper panel) denote the mean drought severity during each period and orange bars (lower panel) denote the mean resistance during each period. Arrows show the directions of changes in drought severity (blue) and resistance (orange) over time.
Extended Data Fig. 10 Biomass-based resistance and resilience in Amazon forests.
a, The spatial pattern of mean resistance derived from the measured above ground biomass in trees for 5 plots in DS drought in tropical South America, derived from Brienen et al., 2015 (ref 84,85). b, The spatial pattern of mean resistance derived from the measured aboveground biomass in trees for 18 plots in WS drought in tropical South America. c, The spatial pattern of mean resistance derived from the measured aboveground biomass in trees for 15 plots in DS+WS drought in tropical South America. (d-f) The same analysis as (a-c) but for biomass-based resilience in (d) DS, (e) WS, and (f) DS+WS drought. g, Mean ln-transformed resistance (ln(Rt)) for plots that experienced DS, WS, and DS+WS droughts in tropical South America. (h) Mean ln-transformed resilience (ln(Rs)) for plots experienced DS, WS, and DS+WS droughts in tropical South America. Boxplots in (g) and (h) show the median (horizontal lines), mean (triangle), 25th, 40th, 60th, and 75th percentiles (i.e. Q0.25, Q0.4, Q0.6, Q0.75; boxes), and maximum and minimum values (i.e. Max and Min; the top and bottom of the whiskers). Significant differences (p < 0.05) among DS, WS, and DS+WS droughts are denoted by different letters for multiple comparisons. The numbers in the bottom of the panels in (g) and (h) represent the magnitude of plots that experienced DS, WS, and DS+WS droughts, respectively.
Supplementary information
Supplementary information
Supplementary Figs. 1–3 and Tables 1 and 2.
Supplementary Table 3
The metadata of 2,935 tree ring sites used in the study, and extrinsic and intrinsic variables related to drought resistance and resilience obtained from publically available sources. The detailed information (identification, sources and references) of the tree ring data and extrinsic and intrinsic variables are listed under ReadMe.
Rights and permissions
About this article
Cite this article
Li, X., Piao, S., Wang, K. et al. Temporal trade-off between gymnosperm resistance and resilience increases forest sensitivity to extreme drought. Nat Ecol Evol 4, 1075–1083 (2020). https://doi.org/10.1038/s41559-020-1217-3
Received:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1038/s41559-020-1217-3
This article is cited by
-
Integrating ecosystem water demands into drought monitoring and assessment under climate change
Nature Water (2024)
-
Divergent growth and responses of conifer and broad-leaved trees to warming-drying climate in a semi-arid region, northern China
European Journal of Forest Research (2024)
-
Dendrochronological studies in the western Himalaya: opportunities, challenges and prospects
Tropical Ecology (2024)
-
Warming-induced vapor pressure deficit suppression of vegetation growth diminished in northern peatlands
Nature Communications (2023)
-
Widespread spring phenology effects on drought recovery of Northern Hemisphere ecosystems
Nature Climate Change (2023)
