Free Standard AU & NZ Shipping For All Book Orders Over $80!
Register      Login
Australian Journal of Botany Australian Journal of Botany Society
Southern hemisphere botanical ecosystems
RESEARCH ARTICLE

Impact of distance to mature forest on the recolonisation of bryophytes in a regenerating Tasmanian wet eucalypt forest

Thomas P. Baker A C , Gregory J. Jordan A , Patrick J. Dalton A and Susan C. Baker A B
+ Author Affiliations
- Author Affiliations

A School of Plant Science, University of Tasmania, Private Bag 55, Hobart, Tas. 7001, Australia.

B Forestry Tasmania, Research and Development Branch, GPO Box 207, Hobart, Tas. 7001, Australia.

C Corresponding author. Email: tpbaker@utas.edu.au

Australian Journal of Botany 61(8) 633-642 https://doi.org/10.1071/BT13250
Submitted: 10 October 2013  Accepted: 15 January 2014   Published: 21 March 2014

Abstract

Forest influence is a type of edge effect that occurs when mature forests affect the recolonisation of adjacent disturbed areas. This can be driven by changes in microclimate conditions near the edge or by an increase in establishment ability with proximity to a propagule source. Bryophyte recolonisation is sensitive to both microclimate and dispersal distance, therefore they are an ideal group to examine how strong forest influence is and over what distance it operates. Responses to forest influence are known to be highly species dependent; therefore, we tested whether distance affects the recolonisation ability of a range of bryophytes. As well as examining a range of species, we tested whether forest influence operated differently on two types of substrate used by bryophytes (logs and ground). For most of the species examined, establishment rates in disturbed forest diminished further away from the mature edge. The influence of unlogged mature forest on bryophyte establishment in harvested forest occurred up to 50 m. Species varied in their response to distance, and the relationships with distance were stronger on the ground compared with log substrates. These results support the concept of forest influence, with areas closer to mature forest experiencing more substantial re-establishment. These findings are relevant to conservation of bryophytes in managed native forests.

Additional keywords: biodiversity, colonisation, dispersal, disturbance, forest influence, microclimate.


References

Avon C, Bergès L, Dumas Y, Dupouey JL (2010) Does the effect of forest roads extend a few meters or more into the adjacent forest? A study on understory plant diversity in managed oak stands. Forest Ecology and Management 259, 1546–1555.
Does the effect of forest roads extend a few meters or more into the adjacent forest? A study on understory plant diversity in managed oak stands.Crossref | GoogleScholarGoogle Scholar |

Baker SC, Read SM (2011) Variable retention silviculture in Tasmania’s wet forests: ecological rationale, adaptive management and synthesis of biodiversity benefits. Australian Forestry 74, 218–232.
Variable retention silviculture in Tasmania’s wet forests: ecological rationale, adaptive management and synthesis of biodiversity benefits.Crossref | GoogleScholarGoogle Scholar |

Baker SC, Richardson AMM, Seeman OD, Barmuta LA (2004) Does clearfell, burn and sow silviculture mimic the effect of wildfire? A field study and review using litter beetles. Forest Ecology and Management 199, 433–448.
Does clearfell, burn and sow silviculture mimic the effect of wildfire? A field study and review using litter beetles.Crossref | GoogleScholarGoogle Scholar |

Baker SC, Spies TA, Wardlaw TJ, Balmer J, Franklin JF, Jordan GJ (2013) The harvested side of edges: effect of retained forests on the re-establishment of biodiversity in adjacent harvested areas. Forest Ecology and Management 302, 107–121.
The harvested side of edges: effect of retained forests on the re-establishment of biodiversity in adjacent harvested areas.Crossref | GoogleScholarGoogle Scholar |

Baldwin LK, Bradfield GE (2007) Bryophyte responses to fragmentation in temperate coastal rainforests: a functional group approach. Biological Conservation 136, 408–422.
Bryophyte responses to fragmentation in temperate coastal rainforests: a functional group approach.Crossref | GoogleScholarGoogle Scholar |

Beever J, Allison KW, Child J (1992) ‘The mosses of New Zealand.’ 2nd edn. (University of Otago Press: Dunedin)

Berg A, Ehnström B, Gustafsson L, Hallingbäck T, Jonsell M, Weslien J (1995) Threat levels and threats to red-listed species in Swedish forests. Conservation Biology 9, 1629–1633.
Threat levels and threats to red-listed species in Swedish forests.Crossref | GoogleScholarGoogle Scholar |

Browning BJ, Jordan GJ, Dalton PJ, Grove S, Wardlaw TJ, Turner PAM (2010) Succession of mosses, liverworts and ferns on coarse woody debris, in relation to forest age and log decay in Tasmanian wet eucalypt forest. Forest Ecology and Management 260, 1896–1905.
Succession of mosses, liverworts and ferns on coarse woody debris, in relation to forest age and log decay in Tasmanian wet eucalypt forest.Crossref | GoogleScholarGoogle Scholar |

Cadenasso ML, Traynor MM, Pickett STA (1997) Functional location of forest edges: gradients of multiple physical factors. Canadian Journal of Forest Research 27, 774–782.
Functional location of forest edges: gradients of multiple physical factors.Crossref | GoogleScholarGoogle Scholar |

Caners RT, Macdonald SE, Belland RJ (2009) Recolonization potential of bryophyte diaspore banks in harvested boreal mixed wood forest. Plant Ecology 204, 55–68.
Recolonization potential of bryophyte diaspore banks in harvested boreal mixed wood forest.Crossref | GoogleScholarGoogle Scholar |

Crites S, Dale MRT (1998) Diversity and abundance of bryophytes, lichens, and fungi in relation to woody substrate and successional stage in aspen mixed wood boreal forests. Botany 76, 641–651.
Diversity and abundance of bryophytes, lichens, and fungi in relation to woody substrate and successional stage in aspen mixed wood boreal forests.Crossref | GoogleScholarGoogle Scholar |

Davies-Colley RJ, Payne GW, van Elswijk M (2000) Microclimate gradients across a forest edge. New Zealand Journal of Ecology 24, 111–121.

Duncan D, Dalton PJ (1982) Recolonisation by bryophytes following fire. Journal of Bryology 12, 53–63.
Recolonisation by bryophytes following fire.Crossref | GoogleScholarGoogle Scholar |

During HJ (1979) Life strategies of bryophytes: a preliminary review. Lindbergia 5, 2–18.

During HJ (2001) Diaspore banks. The Bryologist 104, 92–97.
Diaspore banks.Crossref | GoogleScholarGoogle Scholar |

During HJ (2006) Trends in bryophyte population dynamics. Lindbergia 31, 6–15.

During HJ (2007) Episodic bryophytes in the diaspore bank of a Zimbabwean Savanna. Lindbergia 32, 55–61.

During HJ, Brugués M, Cros RM, Lloret F (1987) The diaspore bank of bryophytes and ferns in the soil in some contrasting habitats around Barcelona, Spain. Lindbergia 13, 137–149.

Dynesius M, Hylander K (2007) Resilience of bryophyte communities to clear-cutting of boreal stream-side forests. Biological Conservation 135, 423–434.
Resilience of bryophyte communities to clear-cutting of boreal stream-side forests.Crossref | GoogleScholarGoogle Scholar |

Dynesius M, Åström M, Nilsson C (2008) Microclimatic buffering by logging residues and forest edges reduces clear-cutting impacts on forest bryophytes. Applied Vegetation Science 11, 345–354.
Microclimatic buffering by logging residues and forest edges reduces clear-cutting impacts on forest bryophytes.Crossref | GoogleScholarGoogle Scholar |

Franklin JF, Berg DR, Thornburgh DA, Tappeiner JC (1997) Alternative silviculture approaches to timber harvesting. In ‘Creating a forestry for the 21st century’. (Eds KA Kohm, JF Franklin) pp. 111–139. (Island Press: Washington)

Frego KA (2007) Bryophytes as potential indicators of forest integrity. Forest Ecology and Management 242, 65–75.
Bryophytes as potential indicators of forest integrity.Crossref | GoogleScholarGoogle Scholar |

Gilbert JM (1959) Forest succession in the Florentine Valley, Tasmania. Papers and Proceedings of the Royal Society of Tasmania 93, 129–151.

Grove S, Meggs J (2003) Coarse woody debris, biodiversity and management: a review with particular reference to Tasmanian wet eucalypt forests. Australian Forestry 66, 258–272.
Coarse woody debris, biodiversity and management: a review with particular reference to Tasmanian wet eucalypt forests.Crossref | GoogleScholarGoogle Scholar |

Grove SJ, Stamm L, Barry C (2009) Log decomposition rates in Tasmanian Eucalyptus obliqua determined using an indirect chronosequence approach. Forest Ecology and Management 258, 389–397.
Log decomposition rates in Tasmanian Eucalyptus obliqua determined using an indirect chronosequence approach.Crossref | GoogleScholarGoogle Scholar |

Gustafsson L, Hallingbäck T (1988) Bryophyte flora and vegetation of managed and virgin coniferous forests in south-west Sweden. Biological Conservation 44, 283–300.
Bryophyte flora and vegetation of managed and virgin coniferous forests in south-west Sweden.Crossref | GoogleScholarGoogle Scholar |

Gustafsson L, Baker SC, Bauhus J, Beese W, Brodie A, Kouki J, Lindenmayer DB, Lõhmus A, Martinez , Pastur G, Messier C, Neyland M, Palik B, Sverdrup-Thygeson A, Volney J, Wayne A, Franklin JF (2012) Retention forestry to maintain multifunctional forests: a world perspective. BioScience 62, 633–645.

Hallingbäck T, Hodgetts N (2000) ‘Status survey and conservation action plan for bryophytes: mosses, liverworts and hornworts.’ (IUCN: Cambridge)

Harper KA, Macdonald SE, Burton PJ, Chen J, Brosofske KD, Saunders SC, Euskirchen ES, Roberts D, Jaiteh MS, Esseen P (2005) Edge influence on forest structure and composition in fragmented landscapes. Conservation Biology 19, 768–782.
Edge influence on forest structure and composition in fragmented landscapes.Crossref | GoogleScholarGoogle Scholar |

Heithecker TD, Halpern CB (2007) Edge-related gradients in microclimate in forest aggregates following structural retention harvests in western Washington. Forest Ecology and Management 248, 163–173.
Edge-related gradients in microclimate in forest aggregates following structural retention harvests in western Washington.Crossref | GoogleScholarGoogle Scholar |

Helle P, Muona J (1985) Invertebrate numbers in edges between clear-fellings and mature forests in northern Finland. Silva Fennnica 19, 281–294.
Invertebrate numbers in edges between clear-fellings and mature forests in northern Finland.Crossref | GoogleScholarGoogle Scholar |

Huggard DJ, Vyse A (2002) Edge effects in high-elevation forests at Sicamous Creek. (Ministry of Forests Science Program, Victoria, British Columbia)

Hylander K (2009) No increase in colonization rate of boreal bryophytes close to propagule sources. Ecology 90, 160–169.
No increase in colonization rate of boreal bryophytes close to propagule sources.Crossref | GoogleScholarGoogle Scholar | 19294922PubMed |

Hylander K, Johnson S (2010) In situ survival of forest bryophytes in small-scale refugia after an intense forest fire. Journal of Vegetation Science 21, 1099–1109.
In situ survival of forest bryophytes in small-scale refugia after an intense forest fire.Crossref | GoogleScholarGoogle Scholar |

Hylander K, Weibull H (2012) Do time-lagged extinctions and colonizations change the interpretation of buffer strip effectiveness? – A study of riparian bryophytes in the first decade after logging. Journal of Applied Ecology 49, 1316–1324.
Do time-lagged extinctions and colonizations change the interpretation of buffer strip effectiveness? – A study of riparian bryophytes in the first decade after logging.Crossref | GoogleScholarGoogle Scholar |

Jarman SJ, Fuhrer B (1995) ‘Mosses and liverworts of rainforest in Tasmania and south-eastern Australia.’ (CSIRO Publishing: Melbourne)

Jarman SJ, Kantvilas G (1994) Lichens and bryophytes of the Tasmanian world heritage area II. Three forest sites at Pelion Plains. Tasforests 6, 103–120.

Johst K, Brandl R, Eber S (2002) Metapopulation persistence in dynamic landscapes: the role of dispersal distance. Oikos 98, 263–270.
Metapopulation persistence in dynamic landscapes: the role of dispersal distance.Crossref | GoogleScholarGoogle Scholar |

Keenan RJ, Kimmin JP (1993) The ecological effects of clear cutting. Environmental Review 1, 121–144.
The ecological effects of clear cutting.Crossref | GoogleScholarGoogle Scholar |

Kimmerer RW (1991) Reproductive ecology of Tetraphis pellucida. II. Differential success of sexual and asexual propagules. The Bryologist 94, 284–288.
Reproductive ecology of Tetraphis pellucida. II. Differential success of sexual and asexual propagules.Crossref | GoogleScholarGoogle Scholar |

Kimmerer RW (2005) Patterns of dispersal and establishment of bryophytes colonizing natural and experimental treefall mounds in northern hardwood forests. The Bryologist 108, 391–401.
Patterns of dispersal and establishment of bryophytes colonizing natural and experimental treefall mounds in northern hardwood forests.Crossref | GoogleScholarGoogle Scholar |

Laaka-Lindberg S, Korpelainen H, Pohjamo M (2003) Dispersal of asexual propagules in bryophytes. The Journal of the Hattori Botanical Laboratory 93, 319–330.

Li Y, Vitt DH (1994) The dynamics of moss establishment: temporal responses to nutrient gradients. The Bryologist 97, 357–364.
The dynamics of moss establishment: temporal responses to nutrient gradients.Crossref | GoogleScholarGoogle Scholar |

Li Y, Vitt DH (1995) The dynamics of moss establishment: temporal responses to a moisture gradient. Journal of Bryology 18, 677–687.
The dynamics of moss establishment: temporal responses to a moisture gradient.Crossref | GoogleScholarGoogle Scholar |

Lindenmayer DB, Franklin JF (1997) Managing stand structure as part of ecologically sustainable forest management in Australian mountain ash forests. Conservation Biology 11, 1053–1068.
Managing stand structure as part of ecologically sustainable forest management in Australian mountain ash forests.Crossref | GoogleScholarGoogle Scholar |

Lindenmayer DB, Franklin JF (2002) ‘Conserving forest biodiversity: a comprehensive multiscaled approach.’ (Island Press: Washington)

Lindenmayer DB, Franklin JF, Lõhmus A, Baker SC, Bauhus Lindenmayer DB, Franklin JF, Lõhmus A, Baker SC, Bauhus (2012) A major shift to the retention approach for forestry can help resolve some global forest sustainability issues. Conservation Letters 5, 421–431.
A major shift to the retention approach for forestry can help resolve some global forest sustainability issues.Crossref | GoogleScholarGoogle Scholar |

Löbel S, Rydin H (2009) Dispersal and life history strategies in epiphyte metacommunities: alternative solutions to survival in patchy, dynamic landscapes. Oecologia 161, 569–579.
Dispersal and life history strategies in epiphyte metacommunities: alternative solutions to survival in patchy, dynamic landscapes.Crossref | GoogleScholarGoogle Scholar | 19579035PubMed |

Longton RE (1997) Reproductive biology and life-history strategies. Advances in Bryology 6, 65–101.

Longton RE, Schuster RM (1983) Reproductive biology. In ‘New manual of bryology. Vol. 1’. (Ed. RM Schuster) pp. 386–462. (The Hattori Botanical Laboratory: Nichinan)

Mallick SA, Driessen MM (2001) ‘Review, risk assessment and management of introduced animals in the Tasmanian wilderness world heritage area.’ (Department of Primary Industries, Parks, Water and Environment, Hobart).

McCarthy P (2003) ‘Catalogue of Australian liverworts and hornworts.’ (Australian Biological Resources Study: Canberra)

Meagher D, Fuhrer B (2003) ‘A field guide to the mosses and allied plants of southern Australia.’ (Australian Biological Resources Study: Canberra)

Miles CJ, Longton RE (1990) The role of spores in reproduction in mosses. Botanical Journal of the Linnean Society 104, 149–173.
The role of spores in reproduction in mosses.Crossref | GoogleScholarGoogle Scholar |

Miles CJ, Longton RE (1992) Deposition of moss spores in relation to distance from parent gametophytes. Journal of Bryology 17, 355–368.
Deposition of moss spores in relation to distance from parent gametophytes.Crossref | GoogleScholarGoogle Scholar |

Millar RB, Anderson MJ, Zunun G (2005) Fitting nonlinear environmental gradients to community data: a general distance-based approach. Ecology 86, 2245–2251.
Fitting nonlinear environmental gradients to community data: a general distance-based approach.Crossref | GoogleScholarGoogle Scholar |

Mitchell SJ, Beese WJ (2002) The retention system: reconciling variable retention with the principles of silvicultural systems. Forestry Chronicle 78, 397–403.

Mueller DMJ, Neumann AJ (1988) Peristome structure and the regulation of spore release in arthrodontous mosses. Advances in Bryology 3, 135–158.

Mueller-Dombois D, Ellenberg H (1974) ‘Aims and methods of vegetation analysis.’ (Wiley: New York)

Muñoz J, Felicísimo AM, Cabezas F, Burgaz AR, Martínez I (2004) Wind as a long-distance dispersal vehicle in the Southern Hemisphere. Science 304, 1144–1147.
Wind as a long-distance dispersal vehicle in the Southern Hemisphere.Crossref | GoogleScholarGoogle Scholar | 15155945PubMed |

Nelson CR, Halpern CB (2005) Short-term effects of timber harvest and forest edges on ground-layer mosses and liverworts. Canadian Journal of Botany 83, 610–620.
Short-term effects of timber harvest and forest edges on ground-layer mosses and liverworts.Crossref | GoogleScholarGoogle Scholar |

Økland R (1996) Are ordination and constrained ordination alternative or complementary strategies in general ecological studies. Journal of Vegetation Science 7, 289–292.
Are ordination and constrained ordination alternative or complementary strategies in general ecological studies.Crossref | GoogleScholarGoogle Scholar |

Pharo EJ, Beattie AJ (2002) The association between substrate variability and bryophyte and lichen diversity in eastern Australian forests. The Bryologist 105, 11–26.
The association between substrate variability and bryophyte and lichen diversity in eastern Australian forests.Crossref | GoogleScholarGoogle Scholar |

Pharo EJ, Zartman CE (2007) Bryophytes in a changing landscape: the hierarchical effects of habitat fragmentation on ecological and evolutionary processes. Biological Conservation 135, 315–325.
Bryophytes in a changing landscape: the hierarchical effects of habitat fragmentation on ecological and evolutionary processes.Crossref | GoogleScholarGoogle Scholar |

Pharo EJ, Lindenmayer DB, Taws N (2004) The effects of large-scale fragmentation on bryophytes in temperate forests. Journal of Applied Ecology 41, 910–921.
The effects of large-scale fragmentation on bryophytes in temperate forests.Crossref | GoogleScholarGoogle Scholar |

Pharo EJ, Meagher DA, Lindenmayer DB (2013) Bryophyte persistence following major fire in eucalypt forest of southern Australia. Forest Ecology and Management 296, 24–32.
Bryophyte persistence following major fire in eucalypt forest of southern Australia.Crossref | GoogleScholarGoogle Scholar |

Pohjamo M, Laaka-Lindberg S, Ovaskainen O, Korpelainen H (2006) Dispersal potential of spores and asexual propagules in the epixylic hepatic Anastrophyllum hellerianum. Evolutionary Ecology 20, 415–430.
Dispersal potential of spores and asexual propagules in the epixylic hepatic Anastrophyllum hellerianum.Crossref | GoogleScholarGoogle Scholar |

Rambo TR, Muir PS (1998) Forest floor bryophytes of Pseudotsuga menziesii-Tsuga heterophylla stands in Oregon: influences of substrate and overstorey. The Bryologist 101, 116–130.

Roberts N, Dalton PJ, Jordan GJ (2003) A species list for the bryophytes and ferns occurring as epiphytes on Tasmanian tree ferns. Hikobia 14, 25–31.

Ross-Davis AL, Frego KA (2002) Comparison of plantations and naturally regenerated clearcuts in the Acadian Forest: forest floor bryophyte community and habitat features. Botany 80, 21–33.

Ross-Davis AL, Frego KA (2004) Propagule sources of forest floor bryophytes: spatiotemporal compositional patterns. The Bryologist 107, 88–97.
Propagule sources of forest floor bryophytes: spatiotemporal compositional patterns.Crossref | GoogleScholarGoogle Scholar |

Rudolphi J, Gustafsson L (2011) Forest regenerating after clear-cutting function as habitat for bryophyte and lichen species of conservation concern. PLoS ONE 6, e18639
Forest regenerating after clear-cutting function as habitat for bryophyte and lichen species of conservation concern.Crossref | GoogleScholarGoogle Scholar | 21490926PubMed |

Schmalholz M, Hylander K (2009) Succession of bryophyte assemblages following clear-cut logging in boreal spruce-dominated forests in south-central Sweden – does retrogressive succession occur? Canadian Journal of Forest Research 39, 1871–1880.
Succession of bryophyte assemblages following clear-cut logging in boreal spruce-dominated forests in south-central Sweden – does retrogressive succession occur?Crossref | GoogleScholarGoogle Scholar |

Schmalholz M, Hylander K (2011) Microtopography creates small-scale refugia for boreal forest floor bryophytes during clear-cut logging. Ecography 34, 637–648.
Microtopography creates small-scale refugia for boreal forest floor bryophytes during clear-cut logging.Crossref | GoogleScholarGoogle Scholar |

Schofield WB (1985) ‘Introduction to bryology.’ (Macmillan Publishing Company: New York)

Scott GAM (1985) ‘Southern Australian liverworts.’ (Australian Government Publishing Service: Canberra)

Snäll T, Fogelqvist J, Ribeiro PJ, Lascoux M (2004) Spatial genetic structure in two congeneric epiphytes with different dispersal strategies analysed by three different methods. Molecular Ecology 13, 2109–2119.
Spatial genetic structure in two congeneric epiphytes with different dispersal strategies analysed by three different methods.Crossref | GoogleScholarGoogle Scholar | 15245387PubMed |

Söderström L, During HJ (2005) Bryophyte rarity viewed from the perspectives of life history strategy and metapopulation dynamics. Journal of Bryology 27, 261–268.
Bryophyte rarity viewed from the perspectives of life history strategy and metapopulation dynamics.Crossref | GoogleScholarGoogle Scholar |

Söderström L, Herben T (1997) Dynamics of bryophyte metapopulations. Advances in Bryology 6, 205–240.

Söderström L, Jonsson BG (1989) Spatial pattern and dispersal in the leafy hepatic Ptilidium pulcherrimum. Journal of Bryology 15, 793–802.
Spatial pattern and dispersal in the leafy hepatic Ptilidium pulcherrimum.Crossref | GoogleScholarGoogle Scholar |

Stone MG (1998) Forest-type mapping by photo-interpretation: a multi-purpose base for Tasmania’s forest management. Tasforests 10, 15–32.

Stoneburner A, Lane DM, Anderson LE (1992) Spore dispersal distances in Atrichum angustatum (Polytrichaceae). The Bryologist 95, 324–328.
Spore dispersal distances in Atrichum angustatum (Polytrichaceae).Crossref | GoogleScholarGoogle Scholar |

Streimann H, Klazenga N (2002) ‘Catalogue of Australian mosses.’ (Australian Biological Resources Study: Canberra)

Sundberg S (2005) Larger capsules enhance short-range spore dispersal in Sphagnum, but what happens further away? Oikos 108, 115–124.
Larger capsules enhance short-range spore dispersal in Sphagnum, but what happens further away?Crossref | GoogleScholarGoogle Scholar |

Swanson ME, Franklin JF, Beschta RL, Crisafulli CM, DellaSala DA, Hutto RL, Lindenmayer DB, Swanson FJ (2011) The forgotten stage of forest succession: early-successional ecosystems on forest sites. Frontiers in Ecology and the Environment 9, 117–125.
The forgotten stage of forest succession: early-successional ecosystems on forest sites.Crossref | GoogleScholarGoogle Scholar |

Tabor J, McElhinny C, Hickey J, Wood J (2007) Colonisation of clearfelled coupes by rainforest tree species from mature mixed forest edges, Tasmania, Australia. Forest Ecology and Management 240, 13–23.
Colonisation of clearfelled coupes by rainforest tree species from mature mixed forest edges, Tasmania, Australia.Crossref | GoogleScholarGoogle Scholar |

Turner PAM (2003) ‘The ecology and conservation of bryophytes in Tasmanian wet eucalypt forest.’ (PhD thesis, University of Tasmania: Hobart)

Turner PAM, Kirkpatrick JB (2009) Do logging, followed by burning, and wildfire differ in their decadal scale effects on tall open-forest bryophytes and vascular plants? Forest Ecology and Management 258, 679–686.
Do logging, followed by burning, and wildfire differ in their decadal scale effects on tall open-forest bryophytes and vascular plants?Crossref | GoogleScholarGoogle Scholar |

Turner MG, Baker WL, Peterson CJ, Peet RK (1998) Factors influencing succession: lessons from large, infrequent natural disturbances. Ecosystems 1, 511–523.
Factors influencing succession: lessons from large, infrequent natural disturbances.Crossref | GoogleScholarGoogle Scholar |

Turner PAM, Kirkpatrick JB, Pharo EJ (2011) Dependence of bryophyte species on young, mature and old growth wet eucalypt forest. Biological Conservation 144, 2951–2957.
Dependence of bryophyte species on young, mature and old growth wet eucalypt forest.Crossref | GoogleScholarGoogle Scholar |

van der Pijl L (1982) ‘Principles of dispersal in higher plants.’ 3rd edn. (Springer-Verlag: Berlin)

van Zanten BO, Pocs T (1981) Distribution and dispersal of bryophytes. Advances in Bryology 1, 479–562.

Vanha-Majamaa I, Lilja S, Ryömä R, Kotiaho JS, Laaka-Lindberg S, Lindberg H, Puttonen P, Tamminen P, Toivanen T, Kuuluvainen T (2007) Rehabilitating boreal forest structure and species composition in Finland through logging, dead wood creation and fire: the EVO experiment. Forest Ecology and Management 250, 77–88.
Rehabilitating boreal forest structure and species composition in Finland through logging, dead wood creation and fire: the EVO experiment.Crossref | GoogleScholarGoogle Scholar |

Werner FA, Gradstein SR (2009) Diversity of dry forest epiphytes along a gradient of human disturbance in the tropical Andes. Journal of Vegetation Science 20, 59–68.
Diversity of dry forest epiphytes along a gradient of human disturbance in the tropical Andes.Crossref | GoogleScholarGoogle Scholar |

Wiens JA (2001) The landscape context of dispersal. In ‘Dispersal’. (Eds J Clobert, E Danchin, AA Dhondt, JD Nichols) pp. 96–109. (Oxford University Press: Oxford)

Wiklund K, Rydin H (2004a) Colony expansion of Neckera pennata: modelled growth rate and effect of microhabitat, competition, and precipitation. The Bryologist 107, 293–301.
Colony expansion of Neckera pennata: modelled growth rate and effect of microhabitat, competition, and precipitation.Crossref | GoogleScholarGoogle Scholar |

Wiklund K, Rydin H (2004b) Ecophysiological constraints on spore establishment in bryophytes. Functional Ecology 18, 907–913.
Ecophysiological constraints on spore establishment in bryophytes.Crossref | GoogleScholarGoogle Scholar |