Abstract
Effects of global warming on radial growth were examined for the subalpine tree species Abies veitchii (1600–2200 m a.s.l.), A. mariesii (2000–2500 m a.s.l.) and Betula ermanii (1600–2500 m a.s.l.) in central Japan, by using dendrochronological techniques. Chronologies of tree-ring widths were examined for the three species and of maximum latewood densities for the two Abies species at their upper and lower distribution limits (total 10 chronologies). We developed multiple regression models to reproduce these chronologies from the monthly mean temperature and sum of precipitation. Of the 10 chronologies, growth-climate relations could not be modeled for tree-ring width chronologies of the three species at their lower distribution limits because of low correlation. Annual mean temperature and annual sum of precipitation will increase about 3 °C and 100 mm, respectively, by 2100 in central Japan, according to 18 climatic change scenarios (6 general circulation models ×3 greenhouse gasses emission scenarios). We predicted tree-ring widths and maximum latewood densities by substituting 18 climatic change scenarios into the growth-climate models. Maximum latewood densities and tree-ring widths of A. mariesii at the upper and lower distribution limits increased by 2100. The rates of the increase tended to be greater for scenarios with more greenhouse gas emission. By contrast, maximum latewood densities of A. veitchii and tree-ring widths of B. ermanii were unchanged by 2100, irrespective of the three greenhouse gas emission scenarios. This study showed that radial growth of the three species responds differently to global warming and their responses are predictable by dendrochronological models.
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Barber VA, Juday GP, Finney BP (2000) Reduced growth of Alaskan white spruce in the twentieth century from temperature-induced drought stress. Nature 405:668–673
Barber VA, Juday GP, Finney BP, Wilmking M (2004) Reconstruction of summer temperatures in interior Alaska from tree-ring proxies: evidence for changing synoptic climate regimes. Clim Change 6:91–120
Briffa KR, Schweingruber FH, Jones PD, Osborn TJ, Shiyatov SG, Vaganov EA (1998) Reduced sensitivity of recent tree-growth to temperature and high northern latitudes. Nature 39:678–682
Buckley BM, Cook ER, Peterson MJ, Barbetti M (1997) A changing temperature response with elevation for Lagarostrobos franklinii in Tasmania, Australia. Clim Change 36:477–498
D’Arrigo RD, Cook ER, Salinger MJ, Palmer J, Krusic PJ, Buckley BM, Villalba R (1998) Tree-ring records from New Zealand: long-term content for recent warming trend. Clim Dyn 14:191–199
D’Arrigo R, Wilson R, Liepert B, Cherubini P (2008) On the ‘Divergence problem’ in northern forests: a review of the tree-ring evidence and possible causes. Glob Planet Change 60:289–305
Davi NK, Jacoby GC, Wiles GC (2003) Boreal temperature variability inferred from maximum latewood density and tree-ring width data, Wrangell Mountain region, Alaska. Quat Res 60:252–262
Diaz SC, Touchan R, Swetnam TW (2001) A tree-ring reconstruction of past precipitation for Baja California Sur, Mexico. Int J Climatol 21:1007–1019
Esper J, Frank D (2009) Divergence pitfalls in tree-ring research. Clim Change 94:261–266
Esper J, Frank DC, Wilson RJS, Briffa KR (2005) Effect of scaling and regression on reconstructed temperature amplitude for the past millennium. Geophys Res Lett 32:L07711
Fonti P, von Arx G, Garcia-Gonzalez I, Eilmann B, Sass-Klaassen U, Gartner H, Eckstein D (2010) Studying global change through investigation of the plastic responses of xylem anatomy in tree rings. New Phytol 185:42–53
Fujimoto S (2008) Estimating the impact of thermal change on broad-leaved tree leaf phenology in the warm temperate zone. Jpn J Conserv Ecol 13:75–87 (in Japanese)
Fujiwara T, Okada N, Yamashita K (1999) Comparison of growth response of Abies and Picea species to climate in Mt. Norikura, central Japan. J Wood Sci 45:92–97
Grudd H, Briffa KR, Karlen W, Bartholin TS, Jones PD, Kromer B (2002) A 7400-year tree-ring chronology in northern Swedish Lapland: natural climatic variability expressed on annual to millennial timescales. Holocene 12:657–665
Guiot J (1990) Methods of calibration. In: Cook ER, Kairiukstis LA (eds) Methods of dendrochronology: applications in the environmental sciences. Kluwer Academic Publ, Boston, pp 165–178
Hamada T (2008) Long-term changes of climatic factors. In: Investigation report for the actual conditions of global warming at Nagano Prefecture. Nagano Environmental Conservation Research Institute, Nagano, pp 3-20 (in Japanese)
Helama S, Lindhom M, Timonen M, Merilainen J, Eronen M (2002) The supra-long Scots pine tree-ring record for Finnish Lapland: Part 2, interannual to centennial variability in summer temperatures for 7500 years. Holocene 12:681–687
Hopton HM, Pederson N (2005) Climate sensitivity of Atlantic white cedar at its northern range limit, Rep. No. General Technical Report SRS-91. USDA Forest Service, Millersville
IPCC (2007) Solomon S, Qin D, Manning M, Chen Z, Marquis M, Averyt KB, Tignor M, Miller HL (eds) Climate change 2007: the physical science basis. Contribution of Working Group I to the fourth assessment report of the Intergovernmental Panel on Climate Change. Cambridge Univ Press, Cambridge
Ishigami Y, Shimizu Y, Omasa K (2003) Projection of climatic change effects on potential natural vegetation distribution in Japan. J Agr Meteorol 59:269–276 (in Japanese)
Ishigami Y, Shimizu Y, Omasa K (2005) Evaluation of the risk to natural vegetation from climate change in Japan. J Agr Meteorol 61:69–75
Iverson LR, Prasad AM (2002) Potential redistribution of tree species habitat under five climate change scenarios in the eastern US. For Ecol Manage 155:205–222
Jacoby GC, D’Arrigo RD (1995) Tree ring width and density evidence of climatic and potential forest change in Alaska. Glob Biogeochem Cyc 9:227–234
Jacoby GC, D’Arrigo RD, Davaajamts T (1996) Mongolian tree rings and 20th-century warming. Science 273:771–773
Japan Meteorological Agency (2011) http://www.jma.go.jp/jma/index.html. Accessed 13 January 2011
Jump A, Hunt JM, Penuelas J (2006) Rapid climate change-related growth decline at the southern range edge of Fagus sylvatica. Glob Change Biol 12:2163–2174
Kelly AE, Goulden ML (2008) Rapid shifts in plant distribution with recent climate change. Proc Nat Acad Sci USA 105:11823–11826
Kira T (1948) On the altitudinal arrangement of climatic zones in Japan. Kanti Nogaku 2:143–173 (in Japanese)
Kirdyanov A, Hughes M, Yaganov E, Schweingruber F, Silkin P (2003) The importance of early summer temperature and date of snow melt for tree growth in the Siberian Subarctic. Trees 17:61–69
Koike T (1988) Leaf structure and photosynthetic performance as related to the forest succession of deciduous broad-leaved trees. Plant Sp Biol 3:77–87
Kujansuu J, Yasue K, Koike T, Abaimov AP, Kajimoto T, Takeda T, Tokumoto M, Matsuura Y (2007) Responses of ring widths and maximum densities of Larix gmelinii to climate on contrasting north- and south-facing slopes in central Siberia. Ecol Res 22:582–592
Laroque CP, Smith DJ (2003) Radial-growth forecasts for five high-elevation conifer species on Vancouver Island, British Columbia. For Ecol Manage 183:313–325
Lenoir J, Gegout JC, Marquet PA, de Ruffray P, Brisse H (2008) A significant upward shift in plant species optimum elevation during the 20th century. Science 320:1768–1771
Leonelli G, Pelfini M, Battipaglia G, Cherubini P (2009) Site-aspect influence on climate sensitivity over time of a high-altitude Pinus cembra tree-ring network. Clim Change 96:185–201
Levanič T, Gričar J, Gagen M, Jalkanen R, Loader NJ, McCarroll D, Oven P, Robertson I (2009) The climate sensitivity of Norway spruse [Picea abies (L.) Karst.] in the southeastern European Alps. Trees 23:169–180
Lloyd AH, Fastie CL (2002) Spatial and temporal variability in the growth and climate response of treeline in Alaska. Clim Change 52:481–509
Miyajima Y, Takahashi K (2007) Changes with altitude of the stand structure of temperate forests on Mount Norikura, central Japan. J For Res 12:187–192
Miyajima Y, Sato T, Takahashi K (2007) Altitudinal changes in vegetation of tree, herb and fern species on Mount Norikura, central Japan. Veg Sci 24:29–40
Oberhuber W, Kofler W, Pfeifer K, Seeber A, Gruber A, Wieser G (2008) Long-term changes in tree-ring-climate relationships at Mt. Patscherkofel (Tyrol, Austria) since the mid-1980s. Trees 22:31–40
Okada M, Iizumi T, Nishimori M, Yokozawa M (2009) Mesh climate change data of Japan Ver. 2 for climate change impact assessments under IPCC SRES A1B and A2. J Agr Meteorol 65:97–109
Penuelas J, Ogaya R, Boada M, Jump AS (2007) Migration, invasion and decline: changes in recruitment and forest structure in a warming-linked shift of European beech forest in Catalonia (NE Spain). Ecography 30:829–837
Piovesan G, Biondi F, Di Filippo A, Alessandrini A, Maugeri M (2008) Drought-driven growth reduction in old beech (Fagus sylvatica L.) forests of the central Apennines, Italy. Glob Change Biol 14:1–17
Rolland C, Petitcolas V, Michalet R (1998) Changes in radial tree growth for Picea abies, Larix decidua, Pinus cembra and Pinus uncinata near the alpine timberline since 1750. Trees 13:40–53
Sato N (2011) Lapse rate on the east slope of Mt. Norikura. MS thesis. Shinshu Univ, Matsumoto (in Japanese)
Savva Y, Oleksyn J, Reich PB, Tjoelker MG, Vaganov EA, Modrzynski J (2006) Interannual growth response of Norway spruce to climate along an altitudinal gradient in the Tatra Mountains, Poland. Trees 20:735–746
Sykes MT, Prentice IC (1996) Climate change, tree species distributions and forest dynamics: a case study in the mixed conifer/northern hardwoods zone of northern Europe. Clim Change 34:161–177
Szeicz JM, MacDonald GM (1995) Dendroclimatic reconstruction of summer temperatures in northwestern Canada since A.D. 1638 based on age-dependent modeling. Quat Res 44:257–266
Takahashi K (2003) Effects of climatic conditions on shoot elongation of alpine dwarf pine (Pinus pumila) at its upper and lower altitudinal limits in central Japan. Arc Antarc Alp Res 35:1–7
Takahashi K, Azuma H, Yasue K (2003) Effects of climate on the radial growth of tree species in the upper and lower distribution limits of an altitudinal ecotone on Mt. Norikura, central Japan. Ecol Res 18:549–558
Takahashi K, Tokumitsu Y, Yasue K (2005) Climatic factors affecting the tree-ring width of Betula ermanii at the timberline on Mount Norikura, central Japan. Ecol Res 20:445–451
Takahashi K, Okuhara I, Tokumitsu Y, Yasue K (2011) Responses to climate by tree-ring widths and maximum latewood densities of two Abies species at upper and lower altitudinal distribution limits in central Japan. Trees 25:745–753
Vaganov EA, Hughes MK, Kirdyanov AV, Schweingruber FH, Silkin PP (1999) Influence of snowfall and melt timing on tree growth in subarctic Eurasia. Nature 400:149–151
Wang XW, Zhao M, Mao ZJ, Zhu SY, Zhang DL, Zhao XZ (2008) Combination of elevated CO2 concentration and elevated temperature and elevated temperature only promote photosynthesis of Quercus mongolica seedlings. Rus J Plant Physiol 55:54–58
Williams AP, Allen CD, Millar CI, Swetnam TW, Michaelsen J, Still CJ, Leavitt SW (2010) Forest responses to increasing aridity and warmth in the southwestern United States. Proc Nat Acad Sci USA 107:21289–21294
Wilmking M, Juday GP, Barber VA, Zald HSJ (2004) Recent climate warming forces contrasting growth responses of white spruce at treeline in Alaska through temperature thresholds. Glob Change Biol 10:1–13
Wimmer R, Grabner M (2000) A comparison of tree-ring features in Picea abies as correlated with climate. IAWA J 21:403–416
Yasue K, Funada R, Kobayashi O, Ohtani J (2000) The effects of tracheid dimensions on variations in maximum density of Picea glehnii and relationships to climatic factors. Trees 14:223–229
Acknowledgments
We are very grateful to Dr. M. Yokozawa for providing us climatic change scenarios and to Dr. K. Yasue for reading an earlier manuscript. This study was partially supported by grants from the Ministry of Education, Culture, Sports, Science and Technology, Japan (Nos. 15710007, 19580168).
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Takahashi, K., Okuhara, I. Forecasting the effects of global warming on radial growth of subalpine trees at the upper and lower distribution limits in central Japan. Climatic Change 117, 273–287 (2013). https://doi.org/10.1007/s10584-012-0547-9
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DOI: https://doi.org/10.1007/s10584-012-0547-9