Abstract
Tree-ring chronologies were developed fromAbies mariesii Masters andPicea jezoensis ssp.hondoensis (Mayr) P. Schmidt collected at different altitudes of Mt. Norikura, central Japan. The tree-ring parameters of ring width and maximum density were measured by soft X-ray densitometry. The measurement series were detrended by fitting a 33-year cubic smoothing spline and autoregressive model. The correlation between species and between sites showed different responses of the species to climate in terms of ring width and maximum density. The correlation coefficient between sites within a species was higher than that between species for a site in the ring width, and the coefficient between species for a site was higher in maximum density. The correlation coefficient between tree-ring chronology and monthly climate data set showed different responses of radial growth to climate. The different response was probably explained by the difference in the length of the growing season. High summer temperature increased the maximum density of the two species and the radial growth inAbies mariesii. Summer precipitation correlated negatively to maximum density, but it did not affect the ring width of either species. The climatic signals could be extracted from ring-width and maximum-density chronologies of both species.
Article PDF
Similar content being viewed by others
References
Fritts HC (1976) Tree rings and climate. Academic, London
Hughes MK, Schweingruber FH, Cartwright D, Kelly PM (1984) July–August temperature at Edinburgh between 1721 and 1975 from tree-ring density and width data. Nature 308:341–344
Cook ER, Kairiukstis LA (1990) Methods of dendrochronology: applications in the environmental sciences. Kluwer, Dordrecht
Briffa KR, Bartholin TS, Eckstein D, Jones PD, Karlen W, Schweingruber FH, Zetterberg P (1990) A 1400-year tree-ring record of summer temperatures in Fennoscandia. Nature 346:434–439
D'Arrigo RD, Barbetti M, Watanasak M, Buckley B, Krusic P, Boonchirdchoo S, Sarutanon S (1997) Progress in dendroclimatic studies of mountain pine in northern Thailand. IAWA J 18:433–444
Park WK, Choi WS. Okada N, Fujiwara T, Ahn WY, Ohta S (1995) Dendrochronological study on global warming in Far East: ring width, density and δ13C analysis ofPinus koraiensis from Mt. Sorak. J Korean For Environ 15:1–6
Yasue K, Funada R, Noda M, Fukazawa K (1994) Dendroclimatological study ofPicea glehnii growing in the Teshio experimental forest of Hokkaido University (in Japanese). Res Bull Hokkaido Univ For 51:243–265
Yasue K, Funada R, Kondo T, Kobayashi O, Fukazawa K (1996) The effect of climatic factors on the radial growth of Japanese ash in northern Hokkaido, Japan. Can J For Res 26:2052–2055
Yasue K, Funada R, Fukazawa K, Ohtani J (1997) Tree-ring width and maximum density of Picea glehnii as indicators of climatic changes in northern Hokkaido, Japan. Can J For Res 27:1962–1970
Sweda T (1994) Dendroclimatological reconstruction for last submillennium in central Japan. Terrestr Atmos Ocean Sci 5:431–442
D'Arrigo RD, Yamaguchi D, Wiles GC, Jacoby GC, Osawa A, Lawrence DM (1997) A kashiwa oak (Quercus dentata) tree-ring width chronology from northern coastal Hokkaido, Japan. Can J For Res 27:613–617
Franklin JF, Maeda T, Ohsumi Y, Matsui M, Yagi H, Hawk GM (1979) Subalpine coniferous forests of central Honshu, Japan. Ecol Monogr 49:311–334
Kaji M (1982) Studies on the ecological geography of subalpine conifers: distribution pattern ofAbies mariesii in relation to the effect of climate in the postglacial warm period (in Japanese). Bull Tokyo Univ For 72:31–120
Cook ER (1985) A time series analysis approach to tree-ring standardization. PhD dissertation, University of Arizona, Tucson
Holmes RL (1983) Computer-assisted quality control in tree-ring dating and measurement. Tree Ring Bull 43:69–78
Cook ER (1990) A conceptual linear aggregate model for tree rings. In: Cook ER, Kairiukstis LA (ed) Methods of dendrochronology: applications in the environmental sciences. Kluwer, Dordrecht, pp 98–104
Cook ER, Briffa KR, Shiyatov S, Mazepa V (1990) Tree-ring standardization and growth-trend estimation. In: Cook ER, Kariukstis LA (eds) Methods of dendrochronology: applications in the environmental sciences. Kluwer, Dordrecht, pp 104–123
Cook ER, Shiyatov S, Mazepa V (1990) Estimation of the mean chronology. In: Cook ER, Kairiukstis LA (eds) Methods of dendrochronology: applications in the environmental sciences. Kluwer, Dordrecht, pp 123–132
Kira T, Yoshino M (1967) Effects of thermal conditions on habitats of Japanese conifers (in Japanese). In: Morishita M, Kira T (eds) Natural history: ecological studies. Chuokoron-sha, Tokyo, pp 133–161
Graumlich LJ (1993) Response of tree growth to climatic variation in the mixed conifer and deciduous forests of the upper Great Lakes region. Can J For Res 23:133–143
Peterson DW, Peterson DL (1994) Effect of climate on radial growth of subalpine conifers in the North Cascade mountains. Can J For Res 24:1921–1932
Kimura M, Mototani I, Hogetsu K (1968) Ecological and physiological studies on the vegetation of Mt. Shimagare VI. Growth and dry matter production of youngAbies stand. But Mag Tokyo 81:287–296
Matsumoto Y, Negishi K (1982) Photosynthesis and respiration in advanced growthAbies veitchii growing under a deep canopy and in the open (in Japanese). J Jpn For Soc 64:165–176
Chiba S (1961) Time of bud burst in inducedAbies andPicea species (in Japanese). Hokkaido Rinbokuikusyu 4(1):18–22
Nobori Y (1994) An analysis of the relationships between weather information and tree ring information of 194 samples fromPicea glehnii Mast. plantation in the Tomakomai district by X-ray densitometry (in Japanese). J Jpn For Soc 76:89–94
Conkey LE (1986) Red spruce tree-ring widths and densities in eastern North America as indicators of past climate. Q Res 26:232–243
Schweingruber FH (1993) Trees and wood in dendrochronology. Springer, Berlin
Author information
Authors and Affiliations
Corresponding author
About this article
Cite this article
Fujiwara, T., Okada, N. & Yamashita, K. Comparison of growth response ofAbies andPicea species to climate in Mt. Norikura, Central Japan. J Wood Sci 45, 92–97 (1999). https://doi.org/10.1007/BF01192324
Received:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/BF01192324