Abstract
Soil chronosequences provide an opportunity to examine the influence of long-term pedogenesis on the biomass and composition of associated tree communities. We assessed variation in the species composition of trees, saplings, and seedlings, and the basal area of adult trees, in lowland temperate rain forest along the Haast chronosequence on the west coast of the South Island of New Zealand. The sequence consists of Holocene dune ridges formed following periodic earthquake disturbance and is characterized by rapid podzol development, including a marked decline in phosphorus concentrations, accumulation of a thick organic horizon, and formation of a cemented iron pan. Tree basal area increased for the first few hundred years and then declined in parallel with the decline in total soil phosphorus, consistent with the concept of forest retrogression. There were also marked changes in the composition of the tree community, from dominance by conifers on young soils to a mixed conifer–angiosperm forest on old soils. Although a variety of factors could account for these changes, partial Mantel tests revealed strong correlations between tree community composition and soil nutrients. The relationships differed among life history stages, however, because the adult tree community composition was correlated strongly with nutrients in the mineral soil, whereas the seedling community composition was correlated with nutrients in the organic horizon, presumably reflecting differences in rooting depth. The changes in the tree community at Haast are consistent with disturbance-related succession in conifer–angiosperm forests in the region, but the opposite of patterns along the nearby Franz Josef post-glacial chronosequence, where conifers are most abundant on old soils. The Haast chronosequence is therefore an important additional example of forest retrogression linked to long-term soil phosphorus depletion, and provides evidence for the role of soil nutrients in determining the distribution of tree species during long-term succession in lowland temperate rain forests in New Zealand.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Berryman KR, Cochran UA, Clark KJ, Biasi GP, Langridge RM, Villamor P (2012) Major earthquakes occur regularly on an isolated plate boundary fault. Science 336:1690–1693
Biffin E, Conran J, Lowe A (2011) Podocarp evolution: a molecular phylogenetic perspective. In: Turner BL, Cernusak LA (eds) Ecology of the Podocarpaeae in tropical forests. Smithsonian Institution Scholarly Press, Washington, DC, pp 1–20
Comita LS, Muller-Landau HC, Aguilar S, Hubbell SP (2010) Asymmetric density dependence shapes species abundances in a tropical tree community. Science 329:330–332
Condit R, Pitman N, Leigh EG, Chave J, Terborgh J, Foster RB, Nunez P, Aguilar S, Valencia R, Villa G, Muller-Landau HC, Losos E, Hubbell SP (2002) Beta-diversity in tropical forest trees. Science 295:666–669
Coomes DA, Bellingham PJ (2011) Temperate and tropical podocarps: how ecologically alike are they? In: Turner BL, Cernusak LA (eds) Ecology of the Podocarpaceae in tropical forests. Smithsonian Institution Scholarly Press, Washington, DC, pp 119–140
Coomes DA, Allen RB, Bentley WA, Burrows LE, Canham CD, Fagan L, Forsyth DM, Gaxiola-Alcantar A, Parfitt RL, Ruscoe WA, Wardle DA, Wilson DJ, Wright EF (2005) The hare, the tortoise and the crocodile: the ecology of angiosperm dominance, conifer persistence and fern filtering. J Ecol 93:918–935
Crews TE, Kitayama K, Fownes JH, Riley RH, Herbert DA, Mueller-Dombois D, Vitousek PM (1995) Changes in soil phosphorus fractions and ecosystem dynamics across a long chronosequence in Hawaii. Ecology 76:1407–1424
Dickinson KJM, Mark AF (1994) Forest–wetland vegetation patterns associated with a Holocene dune–slack sequence, Haast Ecological District, south western New Zealand. J Biogeogr 21:259–281
Duncan RP (1993) Flood disturbance and the coexistence of species in a lowland podocarp forest, south Westland, New Zealand. J Ecol 81:403–416
Eger A, Almond PC, Condron LM (2011) Pedogenesis, soil mass balance, phosphorus dynamics and vegetation communities across a Holocene soil chronosequence in a super-humid climate, South Westland, New Zealand. Geoderma 163:185–196
Fastie CL (1995) Causes and ecosystem consequences of multiple pathways of primary succession at Glacier Bay, Alaska. Ecology 76:1899–1916
Gaxiola A, McNeill SM, Coomes DA (2010) What drives retrogressive succession? Plant strategies to tolerate infertile and poorly drained soils. Funct Ecol 24:714–722
Hedin LO, Vitousek PM, Matson PA (2003) Nutrient losses over four million years of tropical forest development. Ecology 84:2231–2255
Herbert DA, Fownes JH (1999) Forest productivity and efficiency of resource use across a chronosequence of tropical montane soils. Ecosystems 2:242–254
Hurst JM, Allen RB (2007) The RECCE method for describing New Zealand vegetation—expanded manual. Version 4. Landcare Research, Lincoln
Johnson EA, Miyanishi K (2008) Testing the assumptions of chronosequences in succession. Ecol Lett 11:1–13
Kershaw AP, McGlone MS (1995) The quaternary history of the southern conifers. In: Enright NJ, Hill RS (eds) Ecology of the southern conifers. Smithsonian Institution Press, Washington, DC, pp 30–63
Leathwick JR (1995) Climatic relationships of some New Zealand forest tree species. J Veg Sci 6:237–248
Li X, Rapson GL, Flenley JR (2008) Holocene vegetational and climatic history, Sponge Swamp, Haast, south-western New Zealand. Quat Int 184:129–138
Lusk CH, Smith B (1998) Life history differences and tree species coexistence in an old-growth New Zealand rain forest. Ecology 79:795–806
Mark AF, Grealish G, Ward CM, Wilson JB (1988) Ecological studies of a marine terrace sequence in the Waitutu Ecological District of southern New Zealand. Part 1: The vegetation and soil patterns. J R Soc N Z 18:29–58
Molofsky J, Augspurger CK (1992) The effect of leaf litter on early seed establishment in a tropical forest. Ecology 73:68–77
New Zealand Meteorological Service (1983) Summaries of climatological observations to 1980. New Zealand Meteorological Service Miscellaneous Publication 177
Norton DA, Herbert JW, Beveridge AE (1988) The ecology of Dacrydium cupressinum: a review. N Z J Bot 26:37–62
Ogden J (1985) An introduction to plant demography with special reference to New Zealand trees. N Z J Bot 23:751–772
Ogden J, Stewart GH (1995) Community dynamics of the New Zealand conifers. In: Enright NJ, Hill RS (eds) Ecology of the southern conifers. Smithsonian Institution Press, Washington, DC, pp 81–119
Oksanen J (2010) Multivariate analysis of ecological communities in R: vegan tutorial
Palmer RWP, Doyle RB, Grealish GJ, Almond PC (1986) Soil studies in south Westland, 1984/1985. Soil Bureau District Office Report NP 2. Department of Scientific and Industrial Research, New Zealand
Parfitt RL, Ross DJ, Coomes DA, Richardson SJ, Smale MC, Dahlgren RA (2005) N and P in New Zealand soil chronosequences and relationships with foliar N and P. Biogeochemistry 75:305–328
Peltzer DA, Wardle DA, Allison VJ, Baisden WT, Bardgett RD, Chadwick OA, Condron LM, Parfitt RL, Porder S, Richardson SJ, Turner BL, Vitousek PM, Walker J, Walker LR (2010) Understanding ecosystem retrogression. Ecol Monogr 80:509–529
Richardson SJ, Peltzer DA, Allen RB, McGlone MS, Parfitt RL (2004) Rapid development of phosphorus limitation in temperate rainforest along the Franz Josef soil chronosequence. Oecologia 139:267–276
Richardson SJ, Peltzer DA, Allen RB, McGlone MS (2005) Resorption proficiency along a chronosequence: responses among communities and within species. Ecology 86:20–25
Rose AB, Pekelharing CJ, Platt KH (1992) Magnitude of canopy dieback and implications for conservation of southern rata-kamahi (Metrosideros umbellata–Weinmannia racemosa) forests, central Westland, New Zealand. N Z J Ecol 16:23–32
Stevens PR (1968) A chronosequence of soils near the Franz Josef Glacier. Lincoln College, University of Canterbury, Canterbury
Stewart GH, Rose AB (1990) The significance of life history strategies in the developmental history of mixed beech (Nothofagus) forests, New Zealand. Vegetatio 87:101–114
Stewart GH, White JC, Duncan RP (1998) The structure and dynamics of rimu-dominated forests on glacial moraines, South Westland. N Z For 42:22–27
Sydes C, Grime JP (1981) Effects of tree leaf litter on herbaceous vegetation in deciduous woodland. J Ecol 69:249–262
Turner BL, Condron LM, Richardson SJ, Peltzer DA, Allison VJ (2007) Soil organic phosphorus transformations during pedogenesis. Ecosystems 10:1166–1181
Turner BL, Condron LM, Wells A, Andersen KM (2012) Soil nutrient dynamics during podzol development under lowland temperate rain forest. Catena 97:50–62
Veblen TT, Stewart GH (1982) On the conifer regeneration gap in New Zealand: the dynamics of Libocedrus bidwilli stands on South Island. J Ecol 70:413–436
Walker TW, Syers JK (1976) The fate of phosphorus during pedogenesis. Geoderma 15:1–19
Walker J, Thompson CH, Fergus IF, Tunstall BR (1981) Plant succession and soil development in coastal sand dunes of subtropical eastern Australia. In: West DC, Shugart HH, Botkin DB (eds) Forest succession: concepts and application. Springer, New York, pp 107–131
Walker LR, Wardle DA, Bardgett RD, Clarkson BD (2010) The use of chronosequences in studies of ecological succession and soil development. J Ecol 98:725–736
Wardle P (1980) Primary succession in Westland National Park and its vicinity, New Zealand. N Z J Bot 18:221–232
Wardle P (1991) Vegetation of New Zealand. Cambridge University Press, Cambridge
Wardle DA, Zackrisson O, Hörnberg G, Gallet C (1997) The influence of island area on ecosystem properties. Science 277:1296–1299
Wardle DA, Walker LR, Bardgett RD (2004) Ecosystem properties and forest decline in contrasting long-term chronosequences. Science 305:509–513
Wardle DA, Bardgett RD, Walker LR, Peltzer DA, Lagerström A (2008) The response of plant diversity to ecosystem retrogression: evidence from contrasting long-term chronosequences. Oikos 117:93–103
Webb OW, Peart DR (2000) Habitat associations of trees and seedlings in a Bornean rain forest. J Ecol 88:464–478
Wells A, Goff J (2006) Coastal dune ridge systems as chronological markers of palaeoseismic activity: a 650-yr record from southwest New Zealand. Holocene 16:543–550
Wells A, Goff J (2007) Coastal dunes in Westland, New Zealand, provide a record of paleoseismic activity on the Alpine fault. Geology 35:731–734
Wells A, Duncan RP, Stewart GH (2001) Forest dynamics in Westland, New Zealand: the importance of large, infrequent earthquake-induced disturbance. J Ecol 89:1006–1018
Acknowledgments
We thank Peter Bellingham and David Coomes for helpful discussion. Kelly Andersen was supported by a Smithsonian Institution Postdoctoral Fellowship. Funding for travel and consumables was provided by Lincoln University.
Author information
Authors and Affiliations
Corresponding author
Electronic supplementary material
Below is the link to the electronic supplementary material.
Rights and permissions
About this article
Cite this article
Turner, B.L., Wells, A., Andersen, K.M. et al. Patterns of tree community composition along a coastal dune chronosequence in lowland temperate rain forest in New Zealand. Plant Ecol 213, 1525–1541 (2012). https://doi.org/10.1007/s11258-012-0108-3
Received:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s11258-012-0108-3