Growth of Mountain Birch Seedlings in Early-Successional Patches: A Year-Round Perspective

 

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Abstract

Seedlings of mountain birch (Betula pubescens ssp. czerepanovii), a subarctic tree, mainly survive and establish in early-successional patches with low vegetation cover. In particular, during the first years after seed germination, a rapid seedling growth rate is important for winter survival. Seedling growth rate is controlled by plant nitrogen (N) concentration. On a year-round perspective, the N concentration is influenced by N uptake rate during both summer and winter and by N loss during autumn. The aim of the present study was to evaluate the effects of autumn N loss and winter N uptake for seedling growth during summer. The study used young seedlings growing in situ in northern Sweden. Since the growth rate of whole plants cannot be measured in situ, it was estimated using a simple, empirical seedling growth model. The model was based on data from controlled experiments and validated using growth data from a field study. The field study included sequential seedling harvests which were carried out at two sites differing in altitude, from autumn 1994 until autumn 1996. The seedling growth model was used to simulate the effects on growth rate of autumn N losses and winter N uptake. It was found that a decrease in the amount of N lost in autumn and an increase in the amount of N taken up during winter could enhance the growth rate of mountain birch seedlings by the same order of magnitude as an increase in growing season soil temperature by 1 to 2 K.

References

• 01 Aerts,  R.. (1990);  Nutrient use efficiency in evergreen and deciduous species from heathlands.  Oecologia. 84 391-397
  Google Scholar
• 02 Aerts,  R.. (1996);  Nutrient resorption from senescing leaves of perennials: are there general patterns?.  J. Ecol.. 84 597-608
  Google Scholar
• 03 Ågren,  G. I.. (1985);  Theory for growth of plants derived from the nitrogen productivity concept.  Physiol. Plantarum. 64 17-28
  Google Scholar
• 04 Berendse,  F., and Aerts,  R.. (1987);  Nitrogen-use-efficiency: a biologically meaningful definition?.  Funct. Ecol.. 1 293-296
  Google Scholar
• 05 Berkowitz,  A. R.,, Canham,  C. D.,, and Kelly,  V. R.. (1995);  Competition vs. facilitation of tree seedling growth and survival in early successional communities.  Ecology. 76 1156-1168
  Google Scholar
• 06 Chapin,  F. S. III.. (1980);  The mineral nutrition of wild plants.  Ann. Rev. Ecol. Syst.. 11 233-260
  Google Scholar
• 07 Conocer,  W. J., and Iman,  R. L.. (1981);  Rank transformations as a bridge between parametric and nonparametric statistics.  Am. Stat.. 35 124-129
  Google Scholar
• 08 Eckstein,  R. L., and Karlsson,  P. S.. (1997);  Above-ground growth and nutrient use by plants in a subarctic environment: effects of habitat, life-form and species.  Oikos. 79 311-324
  Google Scholar
• 09 Eckstein,  R. L.,, Karlsson,  P. S.,, and Weih,  M.. (1998);  The significance of resorption of leaf resources for shoot growth in evergreen and deciduous plants from a subarctic environment.  Oikos. 81 567-575
  Google Scholar
• 10 Eckstein,  R. L.,, Karlsson,  P. S.,, and Weih,  M.. (1999);  Life span and nutrient resorption as determinants of plant nutrient conservation in temperate-arctic regions.  New Phytol.. 143 177-189
  CrossrefPubMedGoogle Scholar
• 11 Garnier,  E., and Aronson,  J.. (1998) Nitrogen-use efficiency from leaf to stand level: clarifying the concept. Physiological mechanisms and ecological consequences. Lambers, H. et al., eds. Leiden, The Netherlands; Backhuys Publishers pp. 1-24
  Google Scholar
• 12 Glimskär,  A., and Ericsson,  T.. (1999);  Relative nitrogen limitation at steady-state nutrition as a determinant of plasticity in five grassland plant species.  Ann. Bot.. 84 413-420
  CrossrefPubMedGoogle Scholar
• 13 Hirose,  T.. (1988);  Modelling the relative growth rate as a function of plant nitrogen concentration.  Physiol. Plantarum. 72 185-189
  PubMedGoogle Scholar
• 14 Hobbie,  S. E., and Chapin,  F. S. III.. (1998);  An experimental test of limits to tree establishment in Arctic tundra.  J. Ecol.. 86 449-461
  CrossrefPubMedGoogle Scholar
• 15 Hunt,  R.. (1982) Plant growth curves: The functional approach to plant growth analysis. London; Edward Arnold
  Google Scholar
• 16 Karlsson,  P. S., and Nordell,  K. O.. (1996);  Effects of soil temperature on nitrogen economy and growth of mountain birch near its presumed low temperature distribution limit.  Écoscience. 3 183-189
  PubMedGoogle Scholar
• 17 Karlsson,  P. S., and Weih,  M.. (1996);  Relationships between nitrogen economy and performance in the mountain birch (Betula pubescens ssp. tortuosa). .  Ecol. Bull.. 45 71-78
  PubMedGoogle Scholar
• 18 Kullman,  L.. (1986);  Demography of Betula pubescens ssp. tortuosa sown in contrasting habitats close to the birch tree-limit in Central Sweden.  Vegetatio. 65 13-20
  CrossrefPubMedGoogle Scholar
• 19 May,  J. D., and Killingbeck,  K. T.. (1992);  Effects of preventing nutrient resorption on plant fitness and foliar nutrient dynamics.  Ecology. 73 1868-1878
  PubMedGoogle Scholar
• 20 Nordell,  K. O., and Karlsson,  P. S.. (1995);  Resorption of nitrogen and dry matter prior to leaf abscission: variation among individuals, sites and years in the mountain birch.  Funct. Ecol.. 9 326-333
  PubMedGoogle Scholar
• 21 Pollard,  D. F. W., and Wareing,  P. F.. (1968);  Rates of dry-matter production in forest tree seedlings.  Ann. Bot.. 32 573-591
  PubMedGoogle Scholar
• 22 Poorter,  H., and Lewis,  C.. (1986);  Testing differences in relative growth rate: A method avoiding curve fitting and pairing.  Physiol. Plantarum. 67 223-226
  PubMedGoogle Scholar
• 23 Reader,  R. J.. (1978);  Contribution of overwintering leaves to the growth of three broad-leaved, evergreen shrubs belonging to the Ericaceae family.  Can. J. Bot.. 56 1248-1261
  PubMedGoogle Scholar
• 24 SMHI. (1994 - 1996) Årsböcker. Norrköping, Sweden; Swedish Meteorological and Hydrological Institute
  Google Scholar
• 25 Sveinbjörnsson,  B.,, Sonesson,  M.,, Nordell,  K. O.,, and Karlsson,  P. S.. (1993) Performance of mountain birch in different environments in Sweden and Iceland: Implications for afforestation. Forest development in cold climates. Alden, J. et al., eds. New York, USA; Plenum Press pp. 79-87
  Google Scholar
• 26 Walters,  M. B.,, Kruger,  E. L.,, and Reich,  P. B.. (1993);  Relative growth rate in relation to physiological and morphological traits for northern hardwood tree seedlings: species, light environment and ontogenetic considerations.  Oecologia. 96 219-231
  CrossrefPubMedGoogle Scholar
• 27 Weih,  M.. (1998) The Nitrogen Economy of Mountain Birch as Related to Environmental Conditions and Genotype. University of Uppsala, Sweden; Ph. D. Thesis
  Google Scholar
• 28 Weih,  M.. (1998);  Seasonality of nutrient availability in soils of subarctic mountain birch woodlands, Swedish Lapland.  Arct. Alp. Res.. 30 19-25
  PubMedGoogle Scholar
• 29 Weih,  M., and Karlsson,  P. S.. (1997);  Growth and nitrogen utilization in seedlings of mountain birch (Betula pubescens ssp. tortuosa) as related to plant nitrogen status and temperature: A two-year study.  Écoscience. 4 365-373
  PubMedGoogle Scholar
• 30 Weih,  M.,, Karlsson,  P. S.,, and Skre,  O.. (1998);  Intra-specific variation in nitrogen economy among three mountain birch provenances.  Écoscience. 5 108-116
  PubMedGoogle Scholar
• 31 Weih,  M., and Karlsson,  P. S.. (1999);  The nitrogen economy of mountain birch seedlings: inplications for winter survival.  J. Ecol.. 87 211-219
  CrossrefPubMedGoogle Scholar
• 32 Weih,  M., and Karlsson,  P. S.. (1999);  Growth response of altitudinal ecotypes of mountain birch to temperature and fertilisation.  Oecologia. 119 16-23
  CrossrefPubMedGoogle Scholar

M. Weih

Department of Short Rotation Forestry Swedish University of Agricultural Sciences

Box 7016 750 07 Uppsala Sweden

Email: Martin.Weih@LTO.SLU.SE

Section Editor: R. Aerts