The composition and diversity of natural regeneration of tree species in gaps under different intensities of forest disturbance

Maame Esi Hammond , Radek Pokorný , Daniel Okae-Anti , Augustine Gyedu , Irene Otwuwa Obeng

Journal of Forestry Research ›› 2021, Vol. 32 ›› Issue (5) : 1843 -1853.

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Journal of Forestry Research ›› 2021, Vol. 32 ›› Issue (5) : 1843 -1853. DOI: 10.1007/s11676-020-01269-6
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The composition and diversity of natural regeneration of tree species in gaps under different intensities of forest disturbance

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Abstract

The positive ecological interaction between gap formation and natural regeneration has been examined but little research has been carried out on the effects of gaps on natural regeneration in forests under different intensities of disturbance. This study evaluates the composition, diversity, regeneration density and abundance of natural regeneration of tree species in gaps in undisturbed, intermittently disturbed, and disturbed forest sites. Bia Tano Forest Reserve in Ghana was the study area and three gaps each were selected in the three forest site categories. Ten circular subsampling areas of 1 m2 were delineated at 2 m spacing along north, south, east, and west transects within individual gaps. Data on natural regeneration < 350 cm height were gathered. The results show that the intensity of disturbance was disproportional to gap size. Species diversity differed significantly between undisturbed and disturbed sites and, also between intermittently disturbed and disturbed sites for Simpson’s (1-D), Equitability (J), and Berger–Parker (B–P) indices. However, there was no significant difference among forest sites for Shannon diversity (H) and Margalef richness (MI) indices. Tree species composition on the sites differed. Regeneration density on the disturbed site was significantly higher than on the two other sites. Greater abundance and density of shade-dependent species on all sites identified them as opportunistic replacements of gap-dependent pioneers. Pioneer species giving way to shade tolerant species is a natural process, thus make them worst variant in gap regeneration.

Keywords

Disturbed / Intermittently disturbed / Undisturbed / Forest sites / Gap regeneration

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Maame Esi Hammond, Radek Pokorný, Daniel Okae-Anti, Augustine Gyedu, Irene Otwuwa Obeng. The composition and diversity of natural regeneration of tree species in gaps under different intensities of forest disturbance. Journal of Forestry Research, 2021, 32(5): 1843-1853 DOI:10.1007/s11676-020-01269-6

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References

Publishing order | Descend order by publishing year | Descend order by cited within
[1]

Adam KA, Pinard MA, Swaine MD. Nine decades of regulating timber harvest from forest reserves and the status of residual forests in Ghana. Int For Rev, 2006, 8(3): 280-296.
[2]

Agyeman VK, Abu-Juam M, Hawthorne WD (1999) Towards better forest harvesting: a summary of the findings of the research project impact of harvesting on forest mortality and regeneration in the High Forest Zone of Ghana. Forestry Research Program, Project R 6716
[3]

Babweteera F, Plumptre A, Obua J. Effect of gap size and age on climber abundance and diversity in Budongo forest reserve. Uganda Afr J Ecol, 2000, 38(3): 230-237.

[4]

Berger WH, Parker FL. Diversity of planktonic foraminifera in deep-sea sediments. Sci, 1970, 168(3937): 1345-1347.

[5]

Bongers F, Poorter L, Hawthorne WD, Sheil D. The intermediate disturbance hypothesis applies to tropical forests, but disturbance contributes little to tree diversity. Ecol Lett, 2009, 12(8): 798-805.

[6]

Danková L, Saniga M. Canopy gaps and tree regeneration patterns in multi-species unmanaged natural forest Sitno? (Preliminary results). Beskydy, 2013, 6(1): 17-26.

[7]

De Carvalho AL, d'Oliveira MVN, Putz FE, de Oliveira LC. Natural regeneration of trees in selectively logged forest in western Amazonia. For Ecol Manage, 2017, 392: 36-44.

[8]

Denslow JS. Patterns of plant species diversity during succession under different disturbance regimes. Oecologia, 1980, 46(1): 18-21.

[9]

Eilu G, Obua J. Tree condition and natural regeneration in disturbed sites of Bwindi impenetrable forest national park, southwestern Uganda. Trop Ecol, 2005, 46(1): 99-112.
[10]

Fischer R, Bohn F, de Paula MD, Dislich C, Groeneveld J, Gutiérrez AG, Kazmierczak M, Knapp N, Lehmann S, Paulick S, Pütz S. Lessons learned from applying a forest gap model to understand ecosystem and carbon dynamics of complex tropical forests. Ecol Modell, 2016, 326: 124-133.

[11]

Forman RT, Godron M. Landscape ecology, 1986, NY: Wiley 22 28
[12]

Fredericksen TS, Pariona W. Effect of skidder disturbance on commercial tree regeneration in logging gaps in a Bolivian tropical forest. For Ecol Manage, 2002, 171(3): 223-230.

[13]

Hall JB, Swaine MD. Distribution and ecology of vascular plants in a tropical rainforest, 1981, The Hague: Junk Publishers 383

[14]

Hammer Ø, Harper DA, Ryan PD. PAST: paleontological statistics software package for education and data analysis. Palaeontol Electron, 2001, 4(1): 1-9.
[15]

Hammond ME, Pokorný R. Diversity of tree species in gap regeneration under tropical moist semi-deciduous forest: an example from Bia Tano forest reserve. Divers, 2020 12 8 301

[16]

Hammond ME, Pokorný R. Effects of gap size on natural regeneration and micro-environmental soil conditions in European Beech (Fagus sylvatica L.) and Norway Spruce (Picea abies (L.) Karst) dominated mixed forest. Plant Soil Environ, 2020

[17]

Hammond ME, Pokorny R, Dobrovolný L, Friedl M, Hiitola N. Effect of gap size on tree species diversity of natural regeneration–case study from Masaryk training forest school enterprise Křtiny. J For Sci, 2020, 66(10): 1-14.

[18]

Harper DAT. Numerical Palaeobiology: computer-based modelling and analysis of fossils and their distributions, 1999, New york: Wiley 468p
[19]

Hawthorne WD. Ecological profiles of Ghanaian forest trees. Trop For Pap, 1995, 29: 6.
[20]

Hawthorne WD, Gyakari N. Photoguide for the forest trees of Ghana: a tree-spotter's field guide for identifying the largest trees, 2006, Oxford: Oxford Forestry Institute 194 260
[21]

Hawthorne WD, Jongkind CC. Woody plants of western African forests: a guide to the forest trees, shrubs and lianes from Senegal to Ghana, 2006, Kew: Royal Botanic Gardens 10 23
[22]

Herrmann TD (2011) Inventory of natural regeneration and the recovery of logging gaps in the Nkrabia forest reserve in Ghana: a comparison between chainsaw milling and conventional logging. Bachelor thesis, University of Applied Sciences Van Hall Larenstein, Leeuwarden, p 13–30
[23]

Hill JL, Curran PJ. Area, shape and isolation of tropical forest fragments: effects on tree species diversity and implications for conservation. J Biogeogr, 2003, 30(9): 1391-1403.

[24]

Hubbell SP, Foster RB, O'Brien ST, Harms KE, Condit R, Wechsler B, Wright SJ, De Lao SL. Light-gap disturbances, recruitment limitation, and tree diversity in a neotropical forest. Science, 1999, 283(5401): 554-557.

[25]

Ifo SA, Moutsambote JM, Koubouana F, Yoka J, Ndzai SF, Bouetou-Kadilamio LNO Tree species diversity, richness, and similarity in intact and degraded forest in the tropical rainforest of the Congo Basin: case of the forest of Likouala in the Republic of Congo. Int J For Res, 2016, 2016: 1-12.
[26]

Kacholi DS. Edge-interior disparities in tree species and structural composition of the Kilengwe forest in Morogoro region, Tanzania. ISRN Biodivers, 2014, 2014: 1-8.

[27]

Kooch Y, Hosseini SM, Mohammadi J, Hojjati SM. The effects of gap disturbance on soil chemical and biochemical properties in a mixed beech-hornbeam forest of Iran. Ecologia Balkanica, 2010, 2: 39-56.
[28]

Krebs CJ. Ecology: the experimental analysis of distribution and abundance, 2001 5 Vancouver, B.C: The University of British Columbia Press.
[29]

Kuuluvainen T, Laiho R. Long-term forest utilization can decrease forest floor microhabitat diversity: evidence from boreal Fennoscandia. Can J For Res, 2004, 34: 303-309.

[30]

Lawer EA, Baatuuwie BN, Ochire-Boadu K, Asante JW. Preliminary assessment of the effects of anthropogenic activities on vegetation cover and natural regeneration in a moist semi-deciduous forest of Ghana. Int J Ecosys, 2013, 3(5): 148-156.
[31]

Liira J, Sepp T, Kohv K. The ecology of tree regeneration in mature and old forests: combined knowledge for sustainable forest management. J For Res, 2011, 16(3): 184-193.

[32]

Ministry of Lands and Natural Resources, MLNR (2016) Ghana forestry development master plan (2016–2036). Accra, p 167
[33]

Muscolo A, Mallamaci C, Sidari M, Mercurio R. Effects of gap size and soil chemical properties on the natural regeneration in black pine (Pinus nigra Arn.) stands. Tree For Sci Biotechnol, 2011, 5(1): 65-71.
[34]

Oduro KA, Foli EG, Mohre GM, Dumenu WK. General aspects of forestry in Ghana. Sustain Manage Trop Rainfor CELOS Manage Syst, 2011, 14: 242-254.
[35]

Olson DM, Dinerstein E, Wikramanayake ED, Burgess ND, Powell GV, Underwood EC, D’amico JA, Itoua I, Strand HE, Morrison JC, Loucks CJ. Terrestrial Ecoregions of the World: a new map of life on earth: a new global map of terrestrial ecoregions provides an innovative tool for conserving biodiversity. BioSci, 2001, 51(11): 933-938.

[36]

Pardos M, Del Castillo JR, Cañellas I, Montero G. Ecophysiology of natural regeneration of forest stands in Spain. Invest Agrar: Sist Recur For, 2005, 14(3): 434-445.
[37]

Peña-Claros M, Peters EM, Justiniano MJ, Bongers FJJM, Blate GM, Frederickse TS, Putz FE. Regeneration of commercial tree species following silvicultural treatments in a moist tropical forest. For Ecol Manage, 2008, 255(3–4): 1283-1293.

[38]

Raup DM, Crick RE. Measurement of faunal similarity in paleontology. J Paleontol, 1979, 53(5): 1213-1227.
[39]

Rentch JS, Schuler TM, Nowacki GJ, Beane NR, Ford WM. Canopy gap dynamics of second-growth red spruce-northern hardwood stands in West Virginia. For Ecol Manage, 2010, 260(10): 1921-1929.

[40]

Rozendaal DM, Bongers F, Aide TM, Alvarez-Dávila E, Ascarrunz N, Balvanera P, Becknell JM, Bentos TV, Brancalion PH, Cabral GA, Calvo-Rodriguez S. Biodiversity recovery of Neotropical secondary forests. Sci Adv, 2019 5 3 eaau3114

[41]

Schliemann S, Bockheim JG. Methods for studying treefall gaps: a review. For Ecol Manage, 2011, 261(7): 1143-1151.

[42]

Slik JF, Arroyo-Rodrίguez V, Aiba SI, Alvarez-Loayza P, Alves LF, Ashton P, Balvanera P, Bastian ML, Bellingham PJ, Van Den Berg E, Bernacci L. An estimate of the number of tropical tree species. Pro Natl Acad Sci, 2015, 112(24): 7472-7477.

[43]

Toledo M, Poorter L, Peña-Claros M, Alarcón A, Balcázar J, Leaño C, Licona JC, Llanque O, Vroomans V, Zuidema P, Bongers F. Climate is a stronger driver of tree and forest growth rates than soil and disturbance. J Ecol, 2011, 99(1): 254-264.

[44]

Whitmore TC. The vegetation of the Solomon Islands. Biol Sci, 1969, 255(800): 549-566.
[45]

Whitmore TC. Canopy gaps and the two major groups of forest trees. Ecol, 1989, 70(3): 536-538.

[46]

Wiafe ED. Tree regeneration after logging in rain-forest ecosystem. Res J Biol, 2014, 2: 18-28.
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