Patch mosaic cyclic succession associated with the growth and senescence of an alpine shrub
Danielle C. McPhail A and Jamie B. Kirkpatrick A BA Discipline of Geography and Spatial Sciences, School of Land and Food, University of Tasmania, Private Bag 78, GPO, Hobart, Tas. 7001, Australia.
B Corresponding author. Email: j.kirkpatrick@utas.edu.au
Australian Journal of Botany 64(2) 111-119 https://doi.org/10.1071/BT15182
Submitted: 10 August 2015 Accepted: 18 December 2015 Published: 26 February 2016
Abstract
Endogenously-induced cyclic vegetation change has been associated with the life cycle of shrub species, resulting in mosaic or linear patterning in vegetation. We investigated whether mosaic cyclic succession was taking place in Richea acerosa (Lindley) F.Muell. alpine heath on the Central Plateau of Tasmania, Australia by determining the variation in species composition associated with different growth characteristics of the shrub and by monitoring shrubs in plots over 11 years. Temperatures below and adjacent to shrubs were measured in clear sky conditions to determine if microclimatic variation was associated with structural and floristic variation. Species richness was higher outside than inside the shrubs, and was further depressed by an increasing proportion of dead material in the shrub. However, Poa saxicola R.Br. appeared to be protected by the prickly foliage of R. acerosa and also preferentially occurred among the mass of dead stems that characterised the centre of older plants. There was a strong floristic shift associated with the development of the shrub. The live cover of individual shrubs remained constant in all plots over the 11 years, while plots initially dominated by senescent plants contained young plants and vice-versa. The live part of the shrubs moderated temperatures. However, root competition and protection from grazing seem likely to have made a major contribution to the shifting conditions associated with the mosaic cyclic succession.
Additional keywords: alpine succession, heathlands, herbivory.
References
Anderson DJ (1967) Studies on the structure in plant communities. IV. Cyclical succession in Dryas communities from north-west Iceland. Journal of Ecology 55, 629–635.| Studies on the structure in plant communities. IV. Cyclical succession in Dryas communities from north-west Iceland.Crossref | GoogleScholarGoogle Scholar |
Ballantyne M, Pickering CM (2015) Shrub facilitation is an important driver of alpine plant community diversity and functional composition. Biodiversity and Conservation 24, 1859–1875.
| Shrub facilitation is an important driver of alpine plant community diversity and functional composition.Crossref | GoogleScholarGoogle Scholar |
Barclay-Estrup P (1971) The description and interpretation of cyclical processes in heath community. III. Micro-climate in relation to the Calluna cycle. Journal of Ecology 59, 143–166.
Barclay-Estrup P, Gimingham CH (1969) The description and interpretation of cyclical processes in a heath community. I. Vegetational change in relation to the Calluna cycle. Journal of Ecology 57, 737–758.
| The description and interpretation of cyclical processes in a heath community. I. Vegetational change in relation to the Calluna cycle.Crossref | GoogleScholarGoogle Scholar |
Barrow MD, Costin AB, Lake P (1968) Cyclical changes in an Australian fjaeldmark community. Journal of Ecology 56, 89–96.
| Cyclical changes in an Australian fjaeldmark community.Crossref | GoogleScholarGoogle Scholar |
Billings WD, Mooney HA (1968) The ecology of arctic and alpine plants. Biological Reviews of the Cambridge Philosophical Society 43, 481–529.
| The ecology of arctic and alpine plants.Crossref | GoogleScholarGoogle Scholar |
Bokdam J (2001) Effects of browsing and grazing on cyclic succession in nutrient-limited ecosystems. Journal of Vegetation Science 12, 875–886.
| Effects of browsing and grazing on cyclic succession in nutrient-limited ecosystems.Crossref | GoogleScholarGoogle Scholar |
Bridle KL, Kirkpatrick JB, Cullen P, Shepherd RR (2001) Recovery in alpine heath and grassland following burning and grazing, Eastern Central Plateau, Tasmania, Australia. Arctic, Antarctic, and Alpine Research 33, 348–356.
| Recovery in alpine heath and grassland following burning and grazing, Eastern Central Plateau, Tasmania, Australia.Crossref | GoogleScholarGoogle Scholar |
Burrows CJ, McQueen DR, Esler AE, Wardle P (1979) New Zealand heathlands. In ‘Heathlands and related shrublands: descriptive studies’. (Ed. RL Specht) pp. 339–364. (Elsevier Scientific: Amsterdam)
Carr SGM, Turner JS (1962) The role of shrub communities of the Bogong High Plains, Victoria. Proceedings of the Royal Society of Victoria 75, 301–310.
Clark JS (1991) Disturbance and tree life history on the shifting mosaic landscape. Ecology 72, 1102–1118.
| Disturbance and tree life history on the shifting mosaic landscape.Crossref | GoogleScholarGoogle Scholar |
Costin AB, Hallsworth EG, Woof M (1952) Studies in pedogenesis in New South Wales. III. The alpine humus soils. Journal of Soil Science 3, 190–218.
| Studies in pedogenesis in New South Wales. III. The alpine humus soils.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DyaG2cXmvFemug%3D%3D&md5=d781a3301c3f03ac3d8edd58ced5ca17CAS |
Diemont WH, Heil GW (1984) Some long-term observations on cyclical and seral processes in Dutch heathlands. Biological Conservation 30, 283–290.
| Some long-term observations on cyclical and seral processes in Dutch heathlands.Crossref | GoogleScholarGoogle Scholar |
Edwards IJ (1973) Management of water yield. In ‘The lake country’. (Ed. MR Banks) pp. 177–182. (Royal Society of Tasmania: Hobart)
Enright NJ (1989) Heathland vegetation of the Spirits Bay area, far Northern New Zealand. New Zealand Journal of Ecology 12, 63–74.
Gibson N, Kirkpatrick JB (1992) Dynamics of a Tasmanian cushion heath community. Journal of Vegetation Science 3, 647–654.
| Dynamics of a Tasmanian cushion heath community.Crossref | GoogleScholarGoogle Scholar |
Gimingham CH (1972) ‘Ecology of heathlands.’ (Chapman and Hall: London)
Kershaw KA (1960) Cyclic and pattern phenomena as exhibited by Alchemilla alpina. Journal of Ecology 48, 443–453.
| Cyclic and pattern phenomena as exhibited by Alchemilla alpina.Crossref | GoogleScholarGoogle Scholar |
Kershaw KA (1973) ‘Quantitative and dynamic plant ecology.’ (Edward Arnold: London)
Kirkpatrick JB, Bridle KL (2016) Grazing and the absence of fire promote the dominance of an unpalatable shrub in a mosaic cyclic successional system. Australian Journal of Botany 64, 45–50.
| Grazing and the absence of fire promote the dominance of an unpalatable shrub in a mosaic cyclic successional system.Crossref | GoogleScholarGoogle Scholar |
Kirkpatrick JB, Brown MJ (1984) The palaeogeographic significance of local endemism in Tasmanian higher plants. Search 15, 112–113.
Knapp R (1974) ‘Cyclic successions and ecosystem approaches in vegetation dynamics’. In ‘Vegetation dynamics’. (Ed. R Knapp) pp. 91–100. (Dr W Junk Publishers: The Hague)
Lynch AJJ, Kirkpatrick JB (1995) Pattern and process in alpine vegetation and landforms at Hill One, Southern Range, Tasmania. Australian Journal of Botany 43, 537–554.
| Pattern and process in alpine vegetation and landforms at Hill One, Southern Range, Tasmania.Crossref | GoogleScholarGoogle Scholar |
Minchin PR (1990) ‘DECODA user’s manual.’ (Research School of Pacific Studies ANU: Canberra)
Morgan S, Kirkpatrick JB, di Folco M-B (2010) Wind-controlled linear patterning and cyclic succession in Tasmanian Sphagnum mires. Journal of Ecology 98, 583–591.
| Wind-controlled linear patterning and cyclic succession in Tasmanian Sphagnum mires.Crossref | GoogleScholarGoogle Scholar |
Peet RK, Christensen NL (1980) Succession: a population process. Vegetatio 43, 131–140.
| Succession: a population process.Crossref | GoogleScholarGoogle Scholar |
Pharo EJ, Kirkpatrick JB (1994) Vegetation of the alpine sand dunes at Lake Augusta, Tasmania. Australian Journal of Ecology 19, 319–327.
| Vegetation of the alpine sand dunes at Lake Augusta, Tasmania.Crossref | GoogleScholarGoogle Scholar |
Specht RL (1974) ‘The vegetation of South Australia.’ (Government Printer: Adelaide)
Vaartaja O (1949) High surface temperatures: on methods of investigation, and thermocouple observations on a wooded heath in the south of Finland. Oikos 1, 6–28.
| High surface temperatures: on methods of investigation, and thermocouple observations on a wooded heath in the south of Finland.Crossref | GoogleScholarGoogle Scholar |
Watt AS (1947a) Pattern and process in the plant community. Journal of Ecology 35, 1–2.
| Pattern and process in the plant community.Crossref | GoogleScholarGoogle Scholar |
Watt AS (1947b) Contributions to the ecology of bracken. IV. The structure of the community. New Phytologist 46, 97–121.
| Contributions to the ecology of bracken. IV. The structure of the community.Crossref | GoogleScholarGoogle Scholar |
Watt AS (1955) Bracken versus heather, a study in plant sociology. Journal of Ecology 43, 490–506.
| Bracken versus heather, a study in plant sociology.Crossref | GoogleScholarGoogle Scholar |
Whinam J, Cannell EJ, Kirkpatrick JB, Comfort M (1994) Studies on the potential impact of recreational horseriding on some alpine environments of the Central Plateau, Tasmania. Journal of Environmental Management 40, 103–117.
| Studies on the potential impact of recreational horseriding on some alpine environments of the Central Plateau, Tasmania.Crossref | GoogleScholarGoogle Scholar |
Williams RJ, Ashton DH (1988) Cyclical patterns of regeneration in subalpine heathland communities on the Bogong High Plains, Victoria. Australian Journal of Botany 36, 605–619.
| Cyclical patterns of regeneration in subalpine heathland communities on the Bogong High Plains, Victoria.Crossref | GoogleScholarGoogle Scholar |