Natural Regeneration in Tropical Secondary Forest in Southern Amazonia, Brazil

Abstract

The study aimed to establish floral composition, diversity levels, category size, phytosociological structure, commercial use and ecological group of species present in the regeneration of open ombrophile forest in southern Amazon, Brazil. Data were collected at S?o Nicolau farm, in the municipality of Cotrigua?u, northwest of Mato Grosso state, coordinates 51°9'19.5"S and 58°14'53"W. One hundred plots of 10 × 10 m were allocated. All individuals between 29.9 and 59.9 cm had circumference at breast height (CAP) measure, with sub-plots of 5 × 5 m which were measured in all subjects between 1:50 m in height 29.9 cm CAP and sub-plots of 2 × 2 m for individuals between 0.30 to 1.5 m tall. The information obtained in the field were processed in excel spreadsheet. The results showed the occurrence of 610 individuals belonging to 82 species, 34 plant families, with a diversity index of Shannon & Weavers 2.77. The index of value of importance showed species Protium robustum, Maquira calophilla and Inga fagifolium with greater ecological importance in fitocenose. The higher values for Natural Regeneration were the species Protium robustum, Maquira calophilla and Inga fagifolium with 16.42, 8.03 and 7.76 respectively.

 

Share and Cite:

Ebert, A. , Teixeira, L. , Silva, A. & Costa, R. (2014). Natural Regeneration in Tropical Secondary Forest in Southern Amazonia, Brazil. Open Journal of Forestry, 4, 151-160. doi: 10.4236/ojf.2014.42021.

Received November 30th, 2013; revised January 3rd, 2014; accepted January 23rd, 2014

Figure 2.

Distribution of permanent plots, each was subdivided.

The abundance and relative frequency were calculated for each species in each class size, assuming that the denominator is constructed by summing the abundances and absolute fre- quencies of all species in all size classes. Further, it was esti- mated the natural regeneration by size class plant, adding par- tial values ​​of relative frequency and relative abundance of nat- ural regeneration by size class of plant studied, combining them into a unique expression as follows:

where RNCij = estimate of the natural regeneration of the ith species in the jth class of plant size in percentage.

Determined an estimated total natural regeneration by spe- cies using the equation:

where RNTi = estimate of the Natural Regeneration total ith species.

The sum of the RNT of all species, as calculated above, equals 100. Thus, each individual value, either by size class or kind, is being expressed in percentage.

Results

Floristic Composition

The survey for the inventory of natural regeneration of tree species identified a total of 610 individuals belonging to 82 species that are distributed in 34 botanical families. The fami- lies with the highest floristic diversity were: Fabaceae, with 17 genera and 18 species, Moraceae with 5 genera and 5 species, Melastomataceae with 3 genera and 4 species Burceraceae with 2 genera and 4 species, as shown in Table 1.

For diversity analysis, by calculating the diversity index of Shannon & Weaver (H') value obtained was H' = 2.77.

Analysis of the Distribution of Natural Regeneration in Succession Groups

Categorization of natural regeneration of species between ecological groups grouped into size classes resulted in the data listed in Table 2.

It is observed in the prevalence pioneer species, totaling 271 individuals in 33 species, following the climax species with 204 individuals in 19 species and 132 individuals with secondary in 28 species (Figure 3).

These results suggest that the forest in study underwent re- cent exploratory interventions and based on resilience the same, succession processes is still being established, forming an ini- tial structure of natural regeneration. This process is commonly viewed in areas that suffered extensive logging.

In group use of the species studied (Table 3) considered the supply and demand for timber products and non-timber species in the region, detecting a satisfactory number of commercial species, total: 38 species, 31 timber species 5 and the second food producing latex and oil. In the clustering of non-commer- cial trees were identified 44 species, of which at least 5 are used by local communities for the production of medicines, crafts and tool handles. It is noteworthy in this context, the species Siparuna guianensis Aublet used to relieve headaches, and Co-

Table 1.List of species raised in the study area, in alphabetical order by family, common and scientific name and its associated ecological group, and ecological group.

Ecological grouping (EG) = PI, pioneer, SE, secondary, CL, climax, PA, Palmae.

Graphical representation of species by size class in succession stages.

paifera sp which is extracted oil much used in healing wounds and sore throats.

Values ​​of Total Natural Regeneration of tree species with the highest importance, in descending order were; Protium robus- tum 16.42%, Maquira callophylla to 8.03% and Inga fagifo- lium with 7.76% , respectively (Table 4). Can observe the val- ues ​​of natural regeneration studied, with the respective values ​​of absolute abundance by size class of the studied plants. These values ​​allow us to analyze the regeneration by plant size.

Phytosociological Parameters

The total density of natural regeneration was 8.320 individu- als/ha, and the individuals who had the highest values ​​were: Protium robustum, Maquira callophylla, and Mouriri fagifo- lium and Inga sp respectively.

The amounts related to abundance, and absolute and relative frequency of each species Importance Value Index expanded, are shown in Table 5. These values ​​indicate the ecological importance of each species, i.e., its value in fitocenose studied.

The results related to the Amplified Importance Index Value which defines the ecological importance of the species within the community, allows making decisions about the manage- ment techniques based on guarantees replacement of existing individuals.

The species with the highest importance values ​​obtained AIVI refer to tree and shrub species, highlighting the Protium robus- tum, a timber kind suffering strong pressure exploration in the Amazon region; however it is noted that the species responds positively to the processes natural regeneration. Figure 4 graph- ically illustrates the species that showed best AIVI.

Discussion

The current structure of the natural regeneration of the forest studied reflects intense logging in previous years, a fact that establishes succession stages presented. Despite not being able to establish the most intense period of exploration, it was noted that decades after logging still occur marked differences in the floristic composition and structure of ecological succession, especially in places where there were sharp impact on explora- tion, such as creating large clearings, stockyards and skid trails. The results obtained show that the structure of the forest is renewed by natural regeneration in face of disturbances caused by selective harvesting of timber. It’s due probably by the high resilience of local environment.

The structure of natural regeneration in disturbed forests may suffer different arrangements according to the intensity. Hirai et al. (2012) and Garden et al. (2007) studying the effects of log- ging on natural regeneration in a forest, concluded that the flo- ristic composition is modified in areas directly affected during exploitation, suffering changes along the years, occurring natu- ral replacement of species serial stages. Species diversity was considered in a satisfactory level. Studies performed by Gamma et al. (2003), studying the natural regeneration in lowland fo- rests in the Amazon estuary, they obtained similar results with H' = 3.05, for comparison.

Almeida et al. (2012) evaluating phytosociology in managed forest in the municipality of Santarém, in Pará state, obtained H' = 4.39. Probably, the differences found in the results ob- tained in studies of diversity refer to different vegetation types, and/or the intensity of explorations carried out in previous years.

The distribution of the number of plants, as expected, de- creased with increasing class size, put in categories 2 and 3 (changes and changes made) there was considerable decrease of plants, which can be attributed to interspecific competition or related syndromes pollination and/or dispersing agents.

Results show high incidence of commercial species repre- senting the natural regeneration of trees possibly exploited in previous years. Gomes et al. (2011) concluded in their studies conducted in managed rainforest in Bolivia that natural regene- ration of tree species exploited continues after the intervention and does not compromise the structure of the natural regenera- tion of commercial species.

Conclusion

The results obtained in this study lead which species may fuel demand for raw material for timber and non-timber forest products, showing a useful strategy that allows the perpetuation of natural forests, supporting exploratory practices that consider ecological parameters maintenance of intra-and interspecific relationships.

AANR: Absolute Abundance of natural regeneration; ARNR: Abundance concerning natural regeneration; AFNR: Absolute frequency of natural regeneration; RFNR: Relative frequency of natural regeneration; AIVI: Index magnified importance.

Graphic illustration of the species with the highest Amplified Importance Index Value.

Acknowledgements

ONF Brazil for all the logistical support for the work done in the field, and the Coordination of Improvement of Higher Level Personnel―CAPES for the scholarship granted.

References

Conflicts of Interest

The authors declare no conflicts of interest.

References

[1] Almeida, L. S., Gama, J. R. V., Oliveira, F. A., Carvalho, O. P., Gonçalves, D. C. M., & Araújo, G. C. (2012). Fitossociologia e uso múltiplo de espécies arbóreas em floresta manejada, Comunidade Santo Antonio, município de Santarém, Estado do Pará. Acta Amazônica, 42, 185-194.
http://dx.doi.org/10.1590/S0044-59672012000200002
[2] Araújo, C. B. (2011). Composição florística e estrutura de uma floresta densa de terra firme explorada seletivamente no município de Moju, Pará (123 p). Belém: Dissertação de Mestrado, Universidade Federal Rural da Amazônia.
[3] Brasil-Ministério da Minas e Energia. (1982). Levantamento dos recursos naturais—Vol. 20. Projeto RADAMBRASIL. Brasil: Departamento de Produção Mineral.
[4] Calegário, N. (1998). Estudo da regeneração natural, visando à recuperação de áreas degradadas e o manejo florestal. In J. R. S. Scolforo, (Ed.), Manejo florestal (pp. 301-426). Minas Gerais: Universidade Federal de Lavras.
[5] FAO—Food and Agricultural Organization of the United Nations (1971). Silvicultural research in the Amazon National Forestry School (192 p). Curitiba: FAO.
[6] Fontana, C. S., Bencke, G. A., & Reis, R. E. (2003). Livro vermelho da fauna ameaçada de extinção no Rio Grande do Sul (632 p). Porto Alegre: EDIPUCRS.
[7] Frances, L. M. B., Carvalho, J. O. P., & Jardim, F. C. (2007). Mudanças ocorridas na composição florística em decorrência da exploração florestal em uma área de floresta de terra firme na região de Paragominas, PA. Acta Amazônica, 37, 219-228.
http://dx.doi.org/10.1590/S0044-59672007000200007
[8] Gama, J. R. V., Botelho, S. S., & Bentes-Gama, M. M. (2002). Composição florística e estrutura da regeneração natural de floresta secundária de várzea baixa no estuário amazônico. Universidade Federal de Viçosa,Viçosa, Minas Gerais. Revista árvore, 26, 559-566.
[9] Gama, J. R. V., Botelho, S. S., Bentes-Gama, M. M., & Scolforo, J. R. R. (2003). Estrutura e potencial futuro de utilização da regeneração natural de floresta de várzea alta no municipio de Afua, estado do Pará. Ciência Florestal, 13, 71-82.
[10] Gomez, J. W. Le. (2011). Regeneración natural de nueve especies maderables en un bosque intervenido de la Amazonia Boliviana. Acta Amazonica, 41, 135-142.
http://dx.doi.org/10.1590/S0044-59672011000100016
[11] Higushi, N., Jardim, F. C. S., Santos, J., & Alencar, J. C. (1985). Bacia 3—Inventário diagnóstico da regeneração natural. Acta Amazônica, 15, 199-233.
[12] Hirai, H. H., Carvalho, J. R. C., Silva, J. N. M., Carvalho, J. O. P., & Queiroz, W. T. (2012). Efeito da exploração florestal de impacto reduzido sobre a regeneração natural em uma floresta densa de terra firme no município de Paragominas na Amazônia brasileira. Scientia Forestalis, Piracicaba, 40, 306-315.
[13] Instituto Brasileiro do Meio Ambiente e dos Recursos Renováveis— IBAMA (2008). Lista oficial de espécies da flora brasileira ameaçada de extinção. Brasília: Diário Oficial da República Federativa do Brasil.
[14] Jardim, F. C. S., & Hosokawa, R. T. (1986/1987). Estrutura da floresta equatorial úmida da estação experimental de silvicultura tropical do INPA. Manaus, AM. Acta Amazônica, 16-17, 411-508.
[15] Jardim, F. C. S., Serrão, D. R., & Nemer, T. C. (2007). Efeito de diferentes tamanhos de clareiras, sobre o crescimento e a mortalidade de espécies arbóreas, em Moju-PA. Acta Amazônica, 37, 37-48.
http://dx.doi.org/10.1590/S0044-59672007000100004
[16] Lima Filho, D. A., Revilla, J., Coêlho, L. S., Ramos, J. F., Santos, J. L., & Oliveira, J. G. (2002). Regeneração natural de três hectares de floresta ombrófila densa de terra firme na região do Rio Urucu-AM, Brasil. Acta Amazônica, 32, 555-569.
[17] Myers, N. (1992). The primary source: Tropical forests and our future (416 p). New York: W. W. Norteon Inc.
[18] Narvaes, I. S., Longhi, S. J., & Brena, D. A. (2008). Florística e classificação da regeneração natural em floresta ombrófila mista na floresta nacional de São Francisco de Paula, RS. Ciência Florestal, 18, 233-245.
[19] OIMT—Organização Internacional de Madeiras Tropicais (1990). Diretrizes da OIMT para o manejo sustentado de florestas tropicais naturais (18 p). Malaysia: OIMT.
[20] Park, A., Justiniano, M. J., & Fredericksen, T. S. (2005). Natural regeneration and environmental relationships of tree species in logging gaps in a Bolivian tropical forest. Forest Ecology and Management, 217, 147-157. http://dx.doi.org/10.1016/j.foreco.2005.05.056
[21] Péllico Netto, S., & Brena, D. A. (1997). Inventário florestal (p. 316). Curitiba: The Authors Publhisher.
[22] Schneider, R. R. (2000). Amazônia sustentável: Limitantes e oportunidades para o desenvolvimento rural (58 p). Belém: Imazon.
[23] Scolforo. R. S. (1998). Manejo florestal—UFLA/FAEP/DCF (438 p). Lavras: Universidade Federal de Lavras.
[24] Volpato, M. M. L. (1994). Regeneração natural em uma floresta secundaria no domínio de Mata Atlantica: Uma analise fitossociologica (123 p). Dissertação de Mestrado, Viçosa: Universidade Federal de Viçosa.
[25] Zimmerman, B., & Kormos, C. (2012). Prospects for sustainable logging in tropical forests. BioScience, 62, 479-487.
http://dx.doi.org/10.1525/bio.2012.62.5.9

Copyright © 2024 by authors and Scientific Research Publishing Inc.

Creative Commons License

This work and the related PDF file are licensed under a Creative Commons Attribution 4.0 International License.