Abstract
Key message
The frequency of stem-growth cessation in Picea crassifolia has increased significantly as the frequency of extreme climate events has increased.
Abstract
Extreme climatic events are increasingly recognized as important drivers of tree growth, forest dynamics, and range contractions. Understanding tree growth responses to extreme events is important for forest conservation and management, especially under climate change. Here, we studied the patterns of growth cessation of Picea crassifolia Kom., an endemic species to Central Asia, across its distributional range in the Helan Mountains of Northwestern China, to test the hypotheses that (1) tree growth and growth cessations are limited by moisture availability, and (2) that this relationship is constant over the diverse set of conditions covered in our elevational gradient. While tree growth across our gradient was significantly limited by low precipitation in June, we found growth cessation events at the lower distributional margin to increase in severity and frequency in recent decades. We found that the combination of low precipitation early in the monsoon season (June) and high mid-summer (July) vapor pressure deficit likely caused the increased frequency of growth cessation events. Because these populations are already experiencing a high frequency of growth cessation events, the mortality rate of the lower distributional margin trees could further increase if the current trends of decreasing moisture and increasing heat stress continue into the future. Our results strongly suggest that growth cessation events are more than the dendrochronological curiosity they are usually considered to be, and can be important indicators of increased tree growth stress and be potentially useful in identifying tipping points prior to forest change.
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References
Abiyu A, Mokria M, Gebrekirstos A, Bräuning A (2018) Tree-ring record in Ethiopian church forests reveals successive generation differences in growth rates and disturbance events. For Ecol Manag 409:835–844
Alfaro RI, Sickle GAV, Thomson AJ, Wegwitz E (1982) Tree mortality and radial growth losses caused by the western spruce budworm in a Douglas-fir stand in British Columbia. Can J For Res 12:780–787
Allen CD, Breshears DD (1998) Drought-induced shift of a forest–woodland ecotone: Rapid landscape response to climate variation. Proc Natl Acad Sci 95:14839–14842
Allen RG, Pereira LS, Raes D, Smith M (1998) Crop evapotranspiration—guidelines for computing crop water requirements, vol 300. Food and Agriculture Organization of the United Nations, Rome, p D05109
Allen CD, Breshears DD, McDowell NG (2015) On underestimation of global vulnerability to tree mortality and forest die-off from hotter drought in the Anthropocene. Ecosphere 6:1–55
Anderegg WRL, Schwalm C, Biondi F, Camarero JJ, Koch G, Litvak M, Ogle K, Shaw JD, Shevliakova E, Williams AP, Wolf A, Ziaco E, Pacala S (2015) Pervasive drought legacies in forest ecosystems and their implications for carbon cycle models. Science 349:528–532
Babst F, Bouriaud O, Papale D, Gielen B, Janssens IA, Nikinmaa E, Ibrom A, Wu J, Bernhofer C, Köstner B, Grünwald T, Seufert G, Ciais P, Frank D (2014) Above-ground woody carbon sequestration measured from tree rings is coherent with net ecosystem productivity at five eddy-covariance sites. New Phytol 201:1289–1303
Black BA, Griffin D, van der Sleen P, Wanamaker AD, Speer JH, Frank DC, Stahle DW, Pederson N, Copenheaver CA, Trouet V, Griffin S, Gillanders BM (2016) The value of crossdating to retain high-frequency variability, climate signals, and extreme events in environmental proxies. Glob Chang Biol 22:2582–2595
Blasing TJ, Duvick DN, West DC (1981) Dendroclimatic calibration and verification using regionally averaged and single station precipitation data. Tree Ring Bull 1981:37–43
Cailleret M, Jansen S, Robert EMR, Desoto L, Aakala T, Antos JA, Beikircher B, Bigler C, Bugmann H, Caccianiga M, Čada V, Camarero JJ, Cherubini P, Cochard H, Coyea MR, Čufar K, Das AJ, Davi H, Delzon S, Dorman M, Gea-Izquierdo G, Gillner S, Haavik LJ, Hartmann H, Hereş A-M, Hultine KR, Janda P, Kane JM, Kharuk VI, Kitzberger T, Klein T, Kramer K, Lens F, Levanic T, Linares Calderon JC, Lloret F, Lobo-Do-Vale R, Lombardi F, López Rodríguez R, Mäkinen H, Mayr S, Mészáros I, Metsaranta JM, Minunno F, Oberhuber W, Papadopoulos A, Peltoniemi M, Petritan AM, Rohner B, Sangüesa-Barreda G, Sarris D, Smith JM, Stan AB, Sterck F, Stojanović DB, Suarez ML, Svoboda M, Tognetti R, Torres-Ruiz JM, Trotsiuk V, Villalba R, Vodde F, Westwood AR, Wyckoff PH, Zafirov N, Martínez-Vilalta J (2017) A synthesis of radial growth patterns preceding tree mortality. Glob Chang Biol 23:1675–1690
Carbone MS, Czimczik CI, Keenan TF, Murakami PF, Pederson N, Schaberg PG, Xu X, Richardson AD (2013) Age, allocation and availability of nonstructural carbon in mature red maple trees. New Phytol 200:1145–1155
Carter G, Farjon A (2013) Picea crassifolia. The IUCN red list of threatened species 2013: e.T42321A2972306. http://dx.doi.org/10.2305/IUCN.UK.2013-1.RLTS.T42321A2972306.en. Downloaded on 12 February 2018
Cavin L, Jump AS (2017) Highest drought sensitivity and lowest resistance to growth suppression are found in the range core of the tree Fagus sylvatica L. not the equatorial range edge. Glob Chang Biol 23:362–379
Cernusak LA, English NB (2015) Beyond tree-ring widths: stable isotopes sharpen the focus on climate responses of temperate forest trees. Tree Physiol 35:1–3
Chen I-C, Hill JK, Ohlemüller R, Roy DB, Thomas CD (2011) Rapid range shifts of species associated with high levels of climate warming. Science 333:1024–1026
Chen F, Yuan Y-j, Wei W-s, Yu S-l, Fan Z-a, Zhang R-b, Zhang T-w, Li Q, Shang H-m (2012) Temperature reconstruction from tree-ring maximum latewood density of Qinghai spruce in middle Hexi Corridor, China. Theoret Appl Climatol 107:633–643
Ciais P, Reichstein M, Viovy N, Granier A, Ogee J, Allard V, Aubinet M, Buchmann N, Bernhofer C, Carrara A, Chevallier F, De Noblet N, Friend AD, Friedlingstein P, Grunwald T, Heinesch B, Keronen P, Knohl A, Krinner G, Loustau D, Manca G, Matteucci G, Miglietta F, Ourcival JM, Papale D, Pilegaard K, Rambal S, Seufert G, Soussana JF, Sanz MJ, Schulze ED, Vesala T, Valentini R (2005) Europe-wide reduction in primary productivity caused by the heat and drought in 2003. Nature 437:529–533
Cook ER (1985) A time series analysis approach to tree ring standardization. vol Ph.D. University of Arizona, Tucson
Cook BI, Smerdon JE, Seager R, Coats S (2014) Global warming and 21st century drying. Clim Dyn 43:2607–2627
Diffenbaugh NS, Singh D, Mankin JS, Horton DE, Swain DL, Touma D, Charland A, Liu Y, Haugen M, Tsiang M, Rajaratnam B (2017) Quantifying the influence of global warming on unprecedented extreme climate events. Proc Natl Acad Sci 114:4881–4886
Douglass AE (1920) Evidence of climatic effects in the annual rings of trees. Ecology 1:24–32
Dye A, Barker Plotkin A, Bishop D, Pederson N, Poulter B, Hessl A (2016) Comparing tree-ring and permanent plot estimates of aboveground net primary production in three eastern US forests. Ecosphere 7:e01454
Foster JR, D’Amato AW, Bradford JB (2014) Looking for age-related growth decline in natural forests: unexpected biomass patterns from tree rings and simulated mortality. Oecologia 175:363–374
Gao L, Gou X, Deng Y, Yang M, Zhao Z, Cao Z (2013) Dendroclimatic response of Picea crassifolia along an altitudinal gradient in the eastern Qilian Mountains, northwest China. Arctic Antarct Alpine Res 45: 491–499
Geng K, Shan P (1992) The past, present and future of Yinchuan Region: the evolution processes, characteristics and regularities of the late quaternary geographical environment. Surveying and Mapping Press, Beijing
Grundmann BM, Bonn S, Roloff A (2008) Cross-dating of highly sensitive Common beech (Fagus sylvatica L.) tree-ring series with numerous missing rings. Dendrochronologia 26:109–113
Hacket-Pain AJ, Cavin L, Friend AD, Jump AS (2016) Consistent limitation of growth by high temperature and low precipitation from range core to southern edge of European beech indicates widespread vulnerability to changing climate. Eur J Forest Res 135:897–909
HilleRisLambers J, Harsch MA, Ettinger AK, Ford KR, Theobald EJ (2013) How will biotic interactions influence climate change—induced range shifts? Ann N Y Acad Sci 1297:112–125
Holmes RL (1983) Computer-assisted quality control in tree-ring dating and measurement. Tree Ring Bull 43:69–78
Jacoby GC, Sheppard PR, Sieh KE (1988) Irregular recurrence of large earthquakes along the San Andreas fault: evidence from trees. Science 241:196–199
Jiang Y, Kang M, Zhu Y, Xu G (2007) Plant biodiversity patterns on Helan Mountain, China. Acta Oecol 32:125–133
Kharuk VI, Im ST, Oskorbin PA, Petrov IA, Ranson KJ (2013) Siberian pine decline and mortality in southern siberian mountains. For Ecol Manag 310:312–320
Liang E, Shao X, Eckstein D, Huang L, Liu X (2006) Topography- and species-dependent growth responses of Sabina przewalskii and Picea crassifolia to climate on the northeast Tibetan Plateau. For Ecol Manag 236:268–277
Liang E, Shao X, Eckstein D, Liu X (2010) Spatial variability of tree growth along a latitudinal transect in the Qilian Mountains, northeastern Tibetan Plateau. Can J For Res 40:200–211
Liang E, Leuschner C, Dulamsuren C, Wagner B, Hauck M (2016) Global warming-related tree growth decline and mortality on the north-eastern Tibetan plateau. Clim Chang 134:163–176
Liu X (1992) Qinghai spruce. Lanzhou University Press, Lanzhou
Liu F, Kong Y (2015) zoib: an R package for bayesian inference for beta regression and zero/one inflated beta regression. R J 7:34–51
Liu H, Park Williams A, Allen CD, Guo D, Wu X, Anenkhonov OA, Liang E, Sandanov DV, Yin Y, Qi Z, Badmaeva NK (2013) Rapid warming accelerates tree growth decline in semi-arid forests of Inner Asia. Glob Chang Biol 19:2500–2510
Lorimer CG (1985) Methodological considerations in the analysis of forest disturbance history. Can J For Res 15:200–213
Lorimer CG, Dahir SE, Singer MT (1999) Frequency of partial and missing rings in Acer saccharum in relation to canopy position and growth rate. Plant Ecol 143:189–202
Martin-Benito D, Pederson N (2015) Convergence in drought stress, but a divergence of climatic drivers across a latitudinal gradient in a temperate broadleaf forest. J Biogeogr 42:925–937
Martínez-Vilalta J, Lloret F (2016) Drought-induced vegetation shifts in terrestrial ecosystems: the key role of regeneration dynamics. Glob Planet Chang 144:94–108
Mathisen IE, Mikheeva A, Tutubalina OV, Aune S, Hofgaard A (2014) Fifty years of tree line change in the Khibiny Mountains, Russia: advantages of combined remote sensing and dendroecological approaches. Appl Veg Sci 17:6–16
Nehrbass-Ahles C, Babst F, Klesse S, Nötzli M, Bouriaud O, Neukom R, Dobbertin M, Frank D (2014) The influence of sampling design on tree-ring-based quantification of forest growth. Glob Chang Biol 20:2867–2885
Peng J, Gou X, Chen F, Liu P, Zhang Y, Fang K (2007) Characteristics of ring-width chronologies of Picea crassifolia and their responses to climate at different elevations in the Anyemaqen Mountains. Acta Ecol Sin 27:3268–3276
Peñuelas J, Hunt JM, Ogaya R, Jump AS (2008) Twentieth century changes of tree-ring δ13C at the southern range-edge of Fagus sylvatica: increasing water-use efficiency does not avoid the growth decline induced by warming at low altitudes. Glob Chang Biol 14:1076–1088
Peters RL, Groenendijk P, Vlam M, Zuidema PA (2015) Detecting long-term growth trends using tree rings: a critical evaluation of methods. Glob Chang Biol 21:2040–2054
Piao S, Ciais P, Huang Y, Shen Z, Peng S, Li J, Zhou L, Liu H, Ma Y, Ding Y, Friedlingstein P, Liu C, Tan K, Yu Y, Zhang T, Fang J (2010) The impacts of climate change on water resources and agriculture in China. Nature 467:43–51
Poulter B, Pederson N, Liu H, Zhu Z, D’Arrigo R, Ciais P, Davi N, Frank D, Leland C, Myneni R, Piao S, Wang T (2013) Recent trends in Inner Asian forest dynamics to temperature and precipitation indicate high sensitivity to climate change. Agric For Meteorol 178–179:31–45
R Core Team (2017) R: a language and environment for statistical computing. R Foundation for Statistical Computing, Vienna
Settele J, Scholes R, Betts RA, Bunn S, Leadley P, Nepstad D, Overpeck JT, Taboada MA (2015) Terrestrial and inland water systems. In: Field CB, Barros VR, Dokken DJ, Mach KJ, Mastrandrea MD, Bilir TE, Chatterjee M, Ebi KL, Estrada YO, Genova RC, Girma B, Kissel ES, Levy AN, MacCracken S, Mastrandrea PR, White LL (eds) Climate change 2014: impacts, adaptation, and vulnerability. Part A: Global and sectoral aspects. Contribution of working group II to the fifth assessment report of the intergovernmental panel of climate change. Cambridge University Press, Cambridge, pp 271–359
Shrestha KB, Hofgaard A, Vandvik V (2015) Recent treeline dynamics are similar between dry and mesic areas of Nepal, central Himalaya. J Plant Ecol 8:347–358
Siegmund JF, Sanders TGM, Heinrich I, van der Maaten E, Simard S, Helle G, Donner RV (2016) Meteorological drivers of extremes in daily stem radius variations of beech, oak, and pine in northeastern Germany: an event coincidence analysis. Front Plant Sci 7:733
Stokes MA, Smiley TL (1968) An introduction to tree-ring dating. University of Arizona Press, Arizona
Sun Y, Zhang X, Zwiers FW, Song L, Wan H, Hu T, Yin H, Ren G (2014) Rapid increase in the risk of extreme summer heat in Eastern China. Nat Clim Chang 4:1082–1085
Tiwari A, Fan Z-X, Jump AS, Zhou Z-K (2017) Warming induced growth decline of Himalayan birch at its lower range edge in a semi-arid region of Trans-Himalaya, central Nepal. Plant Ecol 218:621–633
Urli M, Lamy J-B, Sin F, Burlett R, Delzon S, Porté AJ (2015) The high vulnerability of Quercus robur to drought at its southern margin paves the way for Quercus ilex. Plant Ecol 216:177–187
Vicente-Serrano SM, Beguería S, López-Moreno JI (2009) A multi-scalar drought index sensitive to global warming: the standardized precipitation evapotranspiration index. J Clim 23:1696–1718
Walter H (1979) Vegetation of the earth and ecological systems of the geo-biosphere. Springer, New York
Wang B, Lin H (2002) Rainy season of the Asian-Pacific summer monsoon. J Clim 15:386–398
Wang A, Lettenmaier DP, Sheffield J (2011) Soil moisture drought in China, 1950–2006. J Clim 24:3257–3271
Young DJN, Stevens JT, Earles JM, Moore J, Ellis A, Jirka AL, Latimer AM (2017) Long-term climate and competition explain forest mortality patterns under extreme drought. Ecol Lett 20:78–86
Yu L, Huang L, Shao X, Xiao F, Wilmking M, Zhang Y (2015) Warming-induced decline of Picea crassifolia growth in the Qilian Mountains in recent decades. PLoS One 10:e0129959
Zackrisson O (1980) Forest fire history: ecological significance and dating problems in the north Swedish boreal forest. Proceedings of the fire history workshop, USDA Forest Service General Technical Report RM-81. Rocky Mountain Forest and Range Experiment Station, Ft. Collins, CO, pp 120–125
Zhang L, Zhou T (2015) Drought over East Asia: a review. J Clim 28:3375–3399
Zhang Y, Wilmking M, Gou X (2009) Changing relationships between tree growth and climate in Northwest China. Plant Ecol 201:39–50
Zhang X, Lei Y, Pang Y, Liu X, Wang J (2014) Tree mortality in response to climate change induced drought across Beijing, China. Clim Chang 124:179–190
Zhang L, Jiang Y, Zhao S, Kang X, Zhang W, Liu T (2017) Lingering response of radial growth of Picea crassifolia to climate at different altitudes in the Qilian Mountains, Northwest China. Trees 31:455–465
Acknowledgements
This work was supported by the National Natural Science Foundation of China (NSFC no. 41630750 and no. 41771051) and China Scholarship Council. We are very grateful to Hui Wang and Jingfan Wang for their help during fieldwork.
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Zhao, S., Jiang, Y., Dong, M. et al. Early monsoon failure and mid-summer dryness induces growth cessation of lower range margin Picea crassifolia. Trees 32, 1401–1413 (2018). https://doi.org/10.1007/s00468-018-1721-0
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DOI: https://doi.org/10.1007/s00468-018-1721-0