Abstract
Reforestation efforts in Ontario have become increasingly more reliant on containerized planting stock since these seedlings are less costly to produce and plant than bare-root stock. Container seedlings, however, tend to be more susceptible to competing vegetation when planted on weed-prone sites often requiring release by chemical herbicides. We have developed cultural techniques to improve the competitiveness of containerized seedlings by promoting initial outplanting performance thus reducing the need for early vegetation control. The approach is based on two new preconditioning practices, exponential fertilization and nutrient loading, which induce a steady-state build up of nutrient reserves in seedlings for outplanting. Exponential nutrient loading integrates these practices with high dose fertilization inducing luxury consumption. Steady-state culture corresponds better with the competitive outplanting environment, since stable internal nutrient accumulation in the greenhouse phase conforms with steady-state nutrient uptake of natural exponentially growing vegetation in the field, and exponential nutrient delivery to container-restricted root systems also better simulates nutrient flux reached by expanding roots in a field soil with constant nutrient availability. Combined with nutrient loading, the higher nutrient reserves and improved nutrient balance in seedlings contribute to enhanced stress resistance and increased growth performance. This paper reviews the theory and practice of exponential nutrient loading during seedling culture, presents results of growth and nutritional responses of seedlings planted on competitive sites, and suggests appropriate criteria for quality testing of nutrient loaded stock.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Benzian, R., Brown, R. M. and Freeman, S. C. R. 1974. Effect of late-season top-dressing of N (and K) applied to conifer transplants in the nursery on their survival and growth on British forest sites. Forestry 47: 153–184.
Bloom, A. J., Chapin, F. S. and Mooney, H. A. 1985. Resources limitation in plants; an economic analogy. Ann. Rev. Ecol. Syst. 16: 369–392.
Burgess, D. 1990. White and black spruce seedling development using the concept of relative addition rate. Scan. J. For. Res. 5: 471–480.
DeHayes, D. H., Ingle, M. A. and Waite, C. E. 1989. Nitrogen fertilization enhances cold tolerance of red spruce seedlings. Can. J. For. Res. 19: 1037–1043.
Fisher, J. T. and Mexal, J. G. 1984. Nutritional management: a physiological basis for yield improvement, pp. 179–224. In: Duryea, M. L. and Brown, G. N. (Eds) Seedling Physiology and Reforestation Success. Martinus Nijhoff/Dr. W. Junk Pubs. Dordrecht/ Boston/Lancaster.
Galloway, R. and Squires, M. F. 1988. The field perspective, pp. 79–85. In: Taking stock: The role of nursery practice in forest renewal. Sept. 14–17. 1987, Kirkland Lake, Ont. Ministry of Supply and Services Canada. Ontario Forestry Research Committee Symposium Proceedings O-P-16.
Gleason, J. F., Duryea, M., Rose, R. and Atkinson, M. 1990. Nursery and field fertilization of 2+0 ponderosa pine seedlings: the effect on morphology, physiology, and field performance. Can. J. For. Res. 20: 1766–1772.
Greaves, R. D., Black, H. C., Hooven, E. F. and Hansen, E. M. 1978. Plantation maintenance, pp. 187–203. In: Cleary, B. D., Greaves, R. D. and Hermann, R. K. (Eds) Regenerating Oregon's Forests. A Guide for the Regeneration Forester. Oregon State Univ. Corvallis.
Imo, M. and Timmer, V. R. 1992a. Nitrogen uptake of mesquite seedlings at conventional and exponential fertilization schedules. Soil Sci. Soc. Am. J. 56: 927–934.
Imo, M. and Timmer, V. R. 1992b. Growth, nutrient allocation and water relations of mesquite (Prosopis chilensis) seedlings under differing fertilization schedules. For. Ecol. Manage. 55: 279–294.
Ingestad, T., and Lund, A.-B. 1986. Theory and techniques for steady-state mineral nutrition and growth of plants. Scan. J. For. Res. 1: 439–453.
Klein, R. M., Perkins, T. F. and Meyers, H. L. 1989. Nutrient status and winter hardiness of red spruce foliage. Can. J. For. Res. 19: 754–758.
Linder, S. and Rook, D. A. 1984. Effects of mineral nutrition on carbon dioxide exchange and partitioning of carbon in trees, pp. 211–236. In: Bowen, G. D. and Nambiar, E. K. S. (Eds) Nutrition of Plantation Forests. Academic Press, London.
MacDonald, G, B. and Weetman, G. F. 1993. Functional growth analysis of conifer seedling response to competing vegetation. For. Chron. 69: 64–70.
Malik, V. S. and Timmer, V. R. 1995. Interaction of nutrient loaded black spruce seedlings with neighbouring vegetation in greenhouse environments. Can J. For. Res. 25: 1017–1023.
Margolis, H.A. and Waring, R. H. 1986. Carbon and nitrogen allocation patterns of Douglas-fir seedlings fertilized with nitrogen in autumn. II. Field performance. Can. J. For. Res. 16: 903–909.
Miller, B. D. and Timmer, V. R. 1994. Steady-state nutrition of Pinus resinosaseedlings: response to nutrient loading, irrigation and hardening regimes. Tree Physiology 14: 1327–1338.
Miller, B. D., Timmer, V. R., Staples, C. and Farentosh, L. 1995. Exponential Fertilization of White Spruce Transplants at Orono Nursery. Nursery Notes No. 130, Queen's Printers for Ontario, 13 pp.
Mullin, R. E. and Bowdery, L. 1977. Effects of seedbed density and nursery fertilization on survival and growth of white spruce. For. Chron. 53: 83–86.
Munson, A. D. and Bernier, P. Y. 1993. Comparing natural and planted black spruce seedlings. II. Nutrient uptake and efficiency of use. Can. J. For. Res. 23: 2435–2442.
Pettersson, S. 1986. Growth, contents of K+ and kinetics of K+ (86Rb) uptake in barley cultured at different supply rates of potassium. Physiol. Plant. 66: 122–128.
Simpson, D. G. 1988. Fixing the Edsel – Can Bareroot Stock Quality be Improved? Proceedings, Combined Meeting of Western Forest Nursery Associations. USDA For. Serv. Gen. Tech. Rep. RM-167. pp. 24–30.
Timmer, V. R. and Armstrong, G. 1987b. Growth and nutrition of containerized Pinus resinosaat exponentially increasing nutrient additions. Can. J. For. Res. 17: 644–647.
Timmer, V. R. and Miller, B. D. 1991. Effects of contrasting fertilization and irrigation regimes on biomass, nutrients, and water relations of container grown red pine seedlings. New Forests 5: 335–348.
Timmer, V. R. and Munson, A. D. 1991. Site-specific growth and nutrient uptake of planted Picea marianain the Ontario Clay Belt. IV. Nitrogen loading response. Can. J. For. Res. 21: 1058–1065.
Timmer, V. R., Armstrong, G. and Miller, B. D. 1991. Steady-state nutrient preconditioning and early outplanting performance of containerized black spruce seedlings. Can. J. For. Res. 21: 585–594.
Troeng, E. and Ackzell, L. 1988. Growth regulation of Scotts pine seedlings with different fertilizer composition and regimes. New Forests 2: 119–130.
van den Driessche, R. 1980. Effects of nitrogen and phosphorus fertilization on Douglas-fir nursery growth and survival after outplanting. Can. J. For. Res. 10: 65–70.
van den Driessche, R. 1985. Late-season fertilization, mineral nutrient reserves, and retranslocation in planted Douglas-fir (Pseudotsuga menziesii(Mirb.) Franco) seedlings. For. Sci. 31: 483–496.
van den Driessche. R. 1988. Nursery growth of conifer seedlings using fertilizers of different solubilities and application time, and their forest growth. Can. J. For. Res. 18: 172–180.
Wood, J. E. and Campbell, R. A. 1988. Planting Stock Specifications/forest Management Operations: Interactions on Productive Boreal Sites. Ontario Forest Research Committee Symposium Proc. O-P-16, pp. 63–70.
Author information
Authors and Affiliations
Rights and permissions
About this article
Cite this article
Timmer, V. Exponential nutrient loading: a new fertilization technique to improve seedling performance on competitive sites. New Forests 13, 279–299 (1997). https://doi.org/10.1023/A:1006502830067
Issue Date:
DOI: https://doi.org/10.1023/A:1006502830067