SciELO - Scientific Electronic Library Online

 
vol.57 issue2Generation of intensity duration frequency curves and intensity temporal variability pattern of intense rainfall for Lages/SCCrude glycerol from biodiesel industry as substrate for biosurfactant production by Bacillus subtilis ATCC 6633 author indexsubject indexarticles search
Home Pagealphabetic serial listing  

Services on Demand

Journal

Article

Indicators

Related links

Share


Brazilian Archives of Biology and Technology

Print version ISSN 1516-8913

Braz. arch. biol. technol. vol.57 no.2 Curitiba Mar./Apr. 2014

http://dx.doi.org/10.1590/S1516-89132014000200018 

ENVIRONMENTAL SCIENCES

 

Management of the environmental restoration of degraded areas

 

 

Izabel Cristina Leinig AraujoI; Maurício DziedzicII; Leila Teresinha MaranhoII, III, *

ICurso de Ciências Biológicas; Universidade Positivo; Curitiba - PR - Brasil
IIPrograma de Pós-graduação em Gestão Ambiental; Universidade Positivo; Curitiba - PR - Brasil
IIIPrograma de Pós-graduação em Biotecnologia Industrial; Universidade Positivo; Curitiba - PR - Brasil

 

 


ABSTRACT

The aim of this work was to study ecotechnology for the management of degraded areas originally covered by the Atlantic Rainforest and located at the coordinates 25º31'50''S, 9º09'30''W. The area included 12 islands, each consisting of six jute bags with 20 kg of substrate (cattle manure and soil transposed from forest fragments). In six of these bags, native plants and seeds were also included. Six additional islands were selected randomly in the vicinity as the control. The process of evaluation was monitored through the chemical and granulometric soil analysis and surveys of survival, biometrics, floristic and phytosociological vegetation. An improvement in soil properties was observed where the model was implemented, which could be attributed to the substrate and re-vegetation. In the floristic and phytosociological studies, out of the 118 identified species, 65 were observed in the first floristic inventory and 86 in the second floristic inventory with similarities between the subfields of 27.69% and 11.36%, respectively. The influence of the substrate seed bank in the implemented islands was also observed. Increased diversity was only significant in the subareas with the model. It was concluded that this technology was effective in accelerating the succession and promoting the beginning of the restoration.

Keywords: restoration ecology, environmental degradation, soil management, revegetation.


 

 

INTRODUCTION

Since the beginning of the industrial and agricultural revolution, environmental degradation has exceeded the rate of ecological conservation (Cairns Jr. 1998). Hence, quite often the restoration of an ecosystem that has been degraded, damaged, altered or completely destroyed as a direct or indirect result of human activity is required (Society for Ecological Restoration International Science and Policy Working Group 2004). Ecological restoration is the process that promotes the recovery of an ecosystem (International Society for Ecological Restoration 2004; Koehler 2005) in order to promote the return of the biological communities to their original state (Jordan et al. 1998).

The development of a restoration model is a process of constant improvement and should consider the conditions of the region where it is deployed (Leite et al. 1994), the implementation of efficient soil management (Prober et al. 2005) and the restoration of species and communities (Palmer et al. 1997). The selection of the species for re-vegetation employs the criteria based on natural occurrence, required light and humidity, ability to adapt to depleted soils and nitrogen fixation, presence of extensive root system and production of edible fruits (Glufke 1999). The monitoring of biological indicators is the key to understanding the evolution of the restoration (Koehler 2005; Jacomel 2008). The analysis of floristic and dimensional structure of the vegetation indicates whether restoration is occurring or not (Araujo et al. 2008; Sávio and Maranho 2008).

The model implemented and evaluated in this study was based on the environmental technology developed by Kesel, Koehler & Associates (KEKO), called Revitec®. This model has already been used by these authors in the regions such as Namibia (Koehler et al. 2006a) and Spain (Koehler et al. 2004, 2006b). Revitec® is described as ideal for ecological restoration of degraded areas, stabilization of areas exposed to erosion and lost soil regeneration (Koehler et al. 2004; Koehler 2005; Koehler et al. 2006a).

The basic model in this jute study was a bag made of a biodegradable cloth, filled with substrate prepared with biotic and abiotic elements (Koehler et al. 2004). The bags protected the substrate and promoted initial erosion control (Koehler et al. 2006a) until, shortly after implantation, the vegetation created erosion barriers. The bags could be arranged linearly or in fertility islands, positioned to capture water in their particles and to disseminate their portions. In the long run, the successional process is expected to propagate (Koehler et al. 2004). This model should be efficient in all aspects of restoration of degraded areas. Furthermore, the use of sustainable and low cost resources (Araujo et al. 2008) should favor its applicability in future projects. The study described herein aimed to evaluate and implement the Revitec® ecotechnology for the restoration of degraded areas, demonstrating that adjustments were deemed necessary.

 

MATERIALS AND METHODS

The study area, initially degraded and eroded, was located in São José dos Pinhais, Paraná, Brazil (25º31'50''S, 49º09'30''W). There were fragments of Atlantic Rainforest adjacent to this area. According to Köppen's classification, the climate was classified as Cfb: mesothermal, humid and super humid (IAPAR, 1994). The experimental modules were composed of islands approximately 1.8 m wide and 2.0 m long and were implemented using the Revitec® model (Fig. 1A). Around this area, additional, untreated, islands of the same size were also randomly selected and monitored as control. Three sample subareas were established: subarea 1, with 6 islands with implantation of vegetation, called islands with vegetation (Fig. 1B); subarea 2, with 6 islands without the implantation of vegetation, called islands without vegetation; and subarea 3, with 6 control islands. In subareas 1 and 2, each island was composed of six jute bags filled with the substrate (Fig. 1A), which was prepared with preserved cattle manure and soil collected from the Atlantic Rainforest fragments located near the experimental area at a ratio of 1:1 (v/v). Twenty kilograms of substrate were placed in each bag (Figs. 1A and 1B).

Each island with vegetation received the bags containing the seedlings of Mimosa scabrella Benth. (Fabaceae) and Sebastiania commersoniana (Baill.) L.B.Sm. & R.J.Downs (Euphorbiaceae) provided by the Environmental Institute of Paraná (IAP). The following species, which represented the plants with pioneer ecophysiological traits collected in the surrounding areas were also sown in these islands: Desmodium adscendens (Sw.) DC. (Fabaceae); Vernonia nitidula Less., Aspilia montevidensis (Spreng.) Kuntze and Bellis sp. (Asteraceae); Schizachyrium condensatum Nees (Poaceae). Two months after the start of the study, Allophylus edulis (A. St.-Hil., A. Juss. & Cambess.) Hieron. ex Niederl. (Sapindaceae) seedlings were also planted in each island with vegetation.

Soil and substrate samples for chemical and granulometric analysis were collected at various points (arranged in a zigzag pattern) at a depth of 0-20 cm throughout the study area prior to the implementation (March 2008) and at end of the experiment (October 2008). Chemical analysis was performed by the laboratory of the Soil and Agricultural Engineering Department at the Universidade Federal do Paraná. A routine composition analysis was performed in the soil samples, including clay fraction and total nitrogen, following the method described by Pavan et al. (1992). The interpretation of the results was performed according to Lima and Sirtoli (2003). The granulometric analysis was carried out according to the Brazilian Standards (NBR) 6508 (Associação Brasileira de Normas Técnicas 1984a) and 7181 (Associação Brasileira de Normas Técnicas 1984b).

The evaluation of the survival index (SI) and biometric index (BI), defined by the height and perimeter of the plants at 15 cm from the ground, were performed monthly for the seedlings of M. scabrella, S. commersoniana and A. edulis. Floristic and phytosociological surveys were conducted in June and October 2008. The material was collected and herbarium specimens were prepared according to the appropriate techniques (Fidalgo and Bononi 1989). Species identification was performed based on available literature and comparison with the collection of the herbarium at the Botanical Museum in the city of Curitiba, state of Parana, Brazil. The species names and their authors were confirmed by consultation to the International Plant Names Index (IPNI).

The evaluation of the succession process was carried out through the assessment of the vegetation structure, which was estimated by the horizontal coverage of individuals of each species. The average degree of coverage for each species was determined using the scale proposed by Braun-Blanquet (1979) considering five categories: coverage between 1 and 10% (average degree of coverage of species i in plot k - gck 5%), between 10 and 25% (gck 17.5%), between 25 and 50% (gck 37.5%), between 50 and 75% (gck 62.5%), and between 75 and 100% (gck 87.5%). Estimates of the following phytosociological parameters were determined: absolute frequency (AF = 100. pi/TP), relative frequency (RF = 100. AF/ΣAF); area of the species (AC = Σgck.ap/100); margin of species in the plot (CV = 100. CA/TA) and margin on the species (RC = 100. CA/ΣCA). Where: pi = number of plots with the presence of species i; TP = total number of plots; ap = area of the plot; TA = total area sampled. The similarity index of Jaccard (Pielou 1975) was employed to estimate the similarity between the subareas. The species diversity was evaluated using the Shannon index (H') (Magurran 1989). The Anderson-Darling test was used to assess the normality of the data and Student's t-test was employed to determine whether the diversity of the subareas was significant, with a significance level of 0.05. Statistical analysis was performed using Statistica for Windows® (Statsoft 2002).

 

RESULTS AND DISCUSSION

It was possible to observe the emergence of seedlings in all the islands in the first visit, one month after the implementation of the study. Germination and colonization of the plants were observed throughout the duration of the study. The highest index of survival of the planted seedlings was observed in S. commersoniana (100%), followed by A. edulis (83.34%) and M. scabrella (16.67%). From June to August 2008, the seedlings of the three implemented species underwent growth (Table 1). This growth was more pronounced immediately after the implantation in June and October. The species of the implemented seeds were suitable for the recovery of degraded areas (Lorenzi 1998; Glufke 1999; Reis and Kageyama 2003) in the locations with unique coverage such as the Atlantic Rainforest, especially on the wet and marshy soils, as observed by Lorenzi (1998). Observed variations in the survival index and growth rate among species were probably due to climatic conditions and characteristics of deciduous and semi-deciduous species (Lorenzi 1998).

Even during the heaviest rainfalls, the islands remained stable and maintained the vegetation. The jute bags, soil from forest fragments, manure, and re-vegetation were essential factors for soil stabilization and erosion control, providing the re-establishment of pioneer species. The ease of applicability of this environmental technology and its ability to adapt to each area and biome characteristics was observed by the use of low cost jute bags and soil and seeds collected in the area's own surroundings.

The jute bags as well as the soil transposed from the forest fragments, preserved cattle manure and re-vegetation were essential factors for soil stabilization and containment of erosion, allowing the restoration of pioneer species, and therefore, the acceleration of ecological succession. Other experiments using the Revitec® model highlighted the importance of these aspects in the context of restoration (Kesel et al. 1999; Koehler et al. 2004; Koehler 2005; Jacomel and Maranho 2005; Koehler et al. 2006a; 2006b; Jacomel 2008).

The presence of the model in the islands and the arrangement of the bags proved to be suitable for the study area, although other authors (Koehler et al. 2004; 2006a) suggested that the bags could be accommodated in different ways such as in a linear or circular fashion. Reis et al. (2007) found that the arrangement of the islands allowed the formation of a center of diversity and the occurrence of natural regeneration in the rest of the area following the characteristic succession stages.

During the study, 118 species were grown in the three subareas. In the first floristic survey conducted in June 2008, there were 65 species, 50 of which belonged to 42 genera, distributed in 16 families, and 15 were not identified (Table 2). The Asteraceae family presented the most representative flora with 20 species, about 31% of the total, followed by Poaceae (8), Fabaceae (4) and Solanaceae (3). In subarea 1, the most representative species was Bulbostylis capillaris (L.) Kunth ex C.B.Clarke with a coverage of 22.86%. This species also had the greatest coverage in subarea 2 (23.53%). In subarea 3, the most representative species were S. angustifolium Reinw. ex de Vriese and Poaceae 1, with coverage of 11.54% each.

On the second survey, in October 2008, 86 species were found, 70 of which belonged to 55 genera distributed in 18 families, and 16 were not identified (Table 2). The Asteraceae was dominant then, with 21 species, accounting for 24.42% of the total, followed by Poaceae (8), Fabaceae (7) and Rubiaceae (4). In subarea 1, the most representative species were B. capillaris (L.) Kunth ex C.B.Clarke and B. decurrens (Vell.) Stellf. with coverage of 26.19% each. The widest coverage in subarea 2, with 19.9%, was also by the species B. capillaris (L.) Kunth ex C.B.Clarke. In subarea 3, S. angustifolium Reinw. ex de Vriese was the most representative species, with a coverage of 57.89%.

The floristic and phytosociological surveys were essential for the analysis of species diversity in each area and also to assess the potential of the environmental technology used in accelerating the succession process. Many authors emphasize the importance of these surveys for the restoration of degraded areas (Moore et al. 1970; Wikum and Shanholtz 1978; Lamb 1998)..

The biggest floristic representativeness of the Asteraceae and Poaceae was also observed in the studies of seed banks of the forest fragments in the state of São Paulo (Baider et al. 2001) and in the application of the Revitec® model in the degraded pastures in the state of Paraná, Brazil (Jacomel 2008). Bulbostylis capillaris (L.) Kunth ex C.B.Clarke was the most prevalent in the subareas where the model was implemented, possibly because of the seed bank. There was high germination of this species in the soil collected in forest fragments that was deposited near the study area. This species was identified in a floristic survey carried out in the urban area of Curitiba, PR and reported as an Atlantic Rainforest native (Biondi and Pedrosa-Macedo 2008). According to Viani and Rodrigues (2009) and Mackenzie and Naeth (2010), salvaged soils could harbor appropriate plant species to develop diverse ecosystems. Baider et al. (2001), Reis et al. (2007) and Schorn et al. (2010) reported that the seed bank allowed recolonization with the seeds and other propagules of pioneer plant species.

Rodrigues et al. (2010) observed that the use of seed banks transposition in forest restoration projects demonstrated to be a viable alternative to stimulate forest succession in degraded areas. However, Baider et al. (2001) suggested that the seed bank alone was not sufficient for restoration, indicating that it was necessary that the seeds were derived from other sources, since frequently the bank did not store in the soil seeds of medium and large woody species, which were tolerant to the shade. In this context, the importance of planting seeds and seedlings of species characteristic of the surrounding forest fragments was evident.

The Shannon index (H') revealed that the highest species diversity was observed in October/2008 in Subarea 1 (1.76 nats/ind.) and Subarea 2 (1.66 nats/ind.). In the control area (Subarea 3), the Shannon index (H') was 1.37 nats/ind. in October/2008. A higher diversity of species was observed in the area where the model was implemented with vegetation (Fig. 2). Significant differences were observed in the Shannon indices (H') for the subareas 1 and 2 between the first (June 2008) and the second assessment (Oct. 2008).

Comparison of the physical and chemical properties of the soil before and after the implementation of the restoration model and between subareas showed improvement of chemical and textural properties. The chemical nature of the soil and substrate (SB) (Table 3) was altered with the implementation of the model. The pH tended to increase in the subareas where the model was implemented, particularly with vegetation. The same was observed for saturation (V%), amount of phosphorus and organic C.

The soil pH, which varied between 5.0 and 7.0 in the study area where the vegetation was implemented, provided a higher range of phosphorus availability (P) for the plants. The pH values observed in the same area prior to the deployment (DS) made this compound remain insoluble (Raij 1991). Moreover, at such low pH values, most of the aluminum was soluble and could cause extreme nutrient deficiency or toxicity to the plants (Delhaize and Ryan 1995; Kochian 1995). The aluminum excess in the soil prevents the development of the root system (Ryan et al. 1993; Delhaize and Ryan 1995; Kochian 1995), resulting in decreased absorption of water and nutrients. A high content of aluminum (m%) and ion exchange capacity (T) were observed in the DS and A3. The highest content of total N was observed in the substrate, followed by A1 and A2. The proportion of clay increased after implantation, being similar in A1 and A2.

Table 4 shows the granulometry results, with the highest percentages of fine sand, silt and clay (material passing the 2.00 mm sieve) observed in the substrate and in the soil where the model was applied. While in subarea 3, the amount of material passing the 0.075 mm sieve was 26.51%, this value reached 65.41% for the substrate and 51.09% for the soil from subarea 2. The highest percentage of medium sand (0.25-0.5 mm) was also observed in SB, A1 and A2. The soil collected before the implementation (degraded soil - DS) showed 11.68% for the equivalent parameter (material passing the 0.075 mm sieve), while the substrate and soil A1 had values above 21%. The largest proportion of coarse sand and gravel (0.5-2.0 mm) was observed in soil A3.

The application of preserved cattle manure contributed to the improvement of the soil´s chemical conditions and the results corroborated the studies that evaluated the aspects of fertilization (Ceretta et al. 2003; Favaretto et al. 2003). Experiments with the use of cattle manure showed changes in the levels of C, Mg, K and P (Favaretto et al. 2003).

Studies on the application of swine manure showed an increase in organic C, total N, P, Mg and Ca and a decrease of Al and K (Ceretta et al. 2003). Another important factor in the edaphic changes was the re-vegetation since the soil in the area where the vegetation was implemented revealed better conditions than the soil of the area with only the substrate and jute bags. Studies using the Revitec® model also showed improvement of the soil´s chemical properties due to re-vegetation and the use of substrate consisting of preserved cattle manure (Jacomel and Maranho 2005; Jacomel 2008).

 

CONCLUSION

The Revitec® model has a low cost of implementation and promoted the containment of erosion, stabilization of soil, and increased availability of nutrients in the soil. Floristic analysis showed that the restoration attained its purpose of accelerating the succession process. The use of native species selected in the vicinity of the study area, as well as the implementation of soil obtained from nearby forest fragments, would allow the adaptation of this technology to any biome. The application of the model could be recommended in restoration projects since it demonstrated to be sustainable and efficient.

 

REFERENCES

ABNT. Associação Brasileira de Normas Técnicas. Grãos de solos que passam na peneira de 4,8 mm: determinação da massa específica. In: Normas Brasileiras - NBR 6508. Rio de Janeiro: ABNT; 1984a.         [ Links ]

ABNT. Associação Brasileira de Normas Técnicas. Solo - Análise Granulométrica. In: Normas Brasileiras - NBR 7181. Rio de Janeiro: ABNT; 1984b.         [ Links ]

Araujo ICL, Bier MC, Maranho LT. Implantação e avaliação de ecotecnologia para recuperação de áreas degradadas: uma proposta com utilização do modelo Revitec®. In: Anais VII Simpósio Nacional sobre Recuperação de Áreas Degradadas; 2008 oct; Curitiba, Brazil. Curitiba: Sociedade Brasileira de Recuperação de Áreas Degradadas (SOBRADE); UFPR; 2008. p. 233 - 245.         [ Links ]

Baider C, Tabarelli M, Mantovani W. The Soil Seed Bank During Atlantic Forest Regeneration in Southeast Brazil. Rev Brasil Biol. 2001; 61(1): 35-44.         [ Links ]

Biondi D, Pedrosa-Macedo JH. Plantas Invasoras Encontradas na Área Urbana de Curitiba (PR). Floresta. 2008; 38 (1): 129-144.         [ Links ]

Braun-Blanquet J. Fitossociologia: Bases para el Estúdio de las Comunidades Vegetales. Madrid: H. Blume Ediciones; 1979.         [ Links ]

Cairns Jr. Eco-societal restoration: rehabilitating homan society's life support system. In: Rana, B.C. (ed). Damaged Ecosystems and Restoration. Delhi: World Scientific; 1998.         [ Links ]

Ceretta CA, Durigon R, Basso CJ, Barcellos LAR, Vieira FCB. Características químicas de solo sob aplicação de esterco líquido de suínos em pastagem natural. Pesq Agropec Bras. 2003; 38 (6): 729-735.         [ Links ]

Delhaize E, Ryan PR. Aluminium Toxicity and Tolerance in Plants. Plant Physiol. 1995; 107, 315-321.         [ Links ]

Favaretto N, Moraes A de, Motta ACV, Prevedello BMS. Efeito da revegetação e da adubação de área degradada na fertilidade do solo e nas características da palhada. Pesq Agropec Bras. 2003; 5(2): 289-297.         [ Links ]

Fidalgo O, Bononi VLR. Técnicas de Coleta, Preservação e Herborização de Material Botânico. São Paulo: Instituto de Botânica; 1989.         [ Links ]

Glufke C. Espécies Florestais Recomendadas para Recuperação de Áreas Degradadas. Porto Alegre: Fundação Zoobotânica do Rio Grande do Sul; 1999.         [ Links ]

Instituto Agronômico do Paraná (IAPAR). Cartas Climáticas do Estado do Paraná. Londrina: IAPAR; 1994.         [ Links ]

Jacomel MSF, Maranho LT. Avaliação de um modelo de recuperação de floresta ombrófila mista (FOM) em áreas degradadas por atividades agropecuárias. RUBs. 2005; 1(4): 9-10.         [ Links ]

Jacomel MSF. Avaliação do Processo de Restauração Ambiental em uma Área de Floresta Ombrófila Mista. Mestrado Profissional em Gestão Ambiental. Curitiba: Universidade Positivo; 2008.         [ Links ]

Jordan WR, Peters RL, Allen EB. Ecological restoration as a biological diversity strategy for conserving. Environ Manage.1998: 12; 55-72.         [ Links ]

Kesel R, Koehler H, Heyser W, Gödeke T. ReviTec® - Eine Neue Integrierte Ökologische Technologie zur Renaturierung Degradierter Standorte. In: Koehler, H., Mathes, K. B. Breckling (Hrsg.). Bodenökologie interdisziplinär. Berlin: Springer; 1999. p. 173-187.         [ Links ]

Koehler H. Applicaton of Ecological Knowledge to Habitat Restoration. In: Barthlott, W., Linsenmaiy, K.E., Porembski, S. Biodiversity: structure and function. Encyclopedia of Life Support Systems (EOLSS), Developed under the Auspices of the UNESCO. Oxford: Eolss Publishers; 2005.         [ Links ]

Koehler H, Fischer K, Radke K. Application of Revitec®: Gender Aspects Case Study Tulongeni (Namibia). In: International Conference "Soil and Desertification - Integrated Research for the Sustainable Management of Soils in Drylands"; 2006 may; Hamburg, Germany. Hamburg: Coordination of Desert Net Germany; 2006a. p. 1-5.         [ Links ]

Koehler H, Kesel R, Heyser W. Revitec® - an Integrated Ecological Technology to Combat Dedradation; First Results from Field experiments in Mallorca (Spain). In: Fourth International Conference on Land Degradation; 2004 sep; Cartagena, Spain. Cartagena: University of Bremenp; 2004. p. 1-5.         [ Links ]

Koehler H, Heyser W, Kesel R. The Ecological Technology Revitec® in Combating Degradation: Concept, First Results, Applications. In: Gao, J., Veste, M., Sun, B. & Beyschlag, W. (eds.). Restoration and Stability of Ecosystems in Arid and Semi-arid Regions. Beijing: Science Press; 2006b.         [ Links ]

Kochian LV. Cellular mechanisms of aluminum toxicity and resistance in plants. Annu Rev Plant Physiol Plant Mol Biol. 1995; 46: 237-260.         [ Links ]

Lamb D. Large-scale ecological restoration of degraded tropical forest lands: The potential role of timber plantations. Restoration Ecol. 1998; 6 (3): 271 - 279.         [ Links ]

Leite LL, Martins CR, Haridasan M. Efeito da Descompactação e Adubação do Solo na Revegetação Espontânea de uma Cascalheira no Parque Nacional de Brasília. In: Anais II Simpósio Sul-americano e I Simpósio Nacional sobre Recuperação de Áreas Degradadas; 1994 nov; Foz do Iguaçu, Brazil. Foz do Iguaçu: Universidade Federal do Paraná; 1994. p. 534-527.         [ Links ]

Lima MR, Sirtoli ÂE. Diagnóstico e Recomendações de Manejo do Solo - Aspectos Teóricos e Metodológicos. Curitiba: Universidade Federal do Paraná; 2003.         [ Links ]

Lorenzi H. Árvores Brasileiras: Manual de Identificação e Cultivo de Plantas Arbóreas do Brasil. Nova Odessa: Plantarum; 1998.         [ Links ]

Magurran AE. Diversidad Ecológica y su Mediación. Barcelona: Vedrá; 1989.         [ Links ]

Mackenzie DD & Naeth MA. The role of the forest soil propagule bank in assisted natural recovery after oil sands mining. Restoration Ecol. 2010; 18 (4): 418-427.         [ Links ]

Moore JJ, Fitzsimons SJP, Lambe E, White J. A comparision and evalution of some phytosociological techniques. Plant Ecol. 1970; 20 (1-4): 1-20.         [ Links ]

Palmer MA, Ambrose RF, Poff NL. Ecological theory and community restoration ecology. Restoration Ecol. 1997; 5 (4): 291-300.         [ Links ]

Pavan MA, Bloch MF, Zempulski HC, Miyazawa M, Zocoler DC. 1992. Manual de análise química de solo e controle de qualidade. Londrina: IAPAR (Circular 76); 1992.         [ Links ]

Pielou EC. Ecological Diversity. New York: John Wiley & Sons; 1975.         [ Links ]

Prober SM, Thiele K, Lunt I, Koen TB. Restoring ecological function in temperate grassy woodlands - manipulating soil nutrients, annual exotics and native perennial grasses through carbon supplements and spring burns. J Appl Ecol. 2005; 42: 1073-1085.         [ Links ]

Raij BV. Fertilidade do Solo e Adubação. Piracicaba: Editora Agronômica; 1991.         [ Links ]

Reis A, Kageyama PY. Restauração de áreas degradadas utilizando interações interespecíficas. In: Kageyama PY, Oliveira RE, Moraes LFD, Engel VL, Gandara FB (org.) Restauração ecológica de Ecossistemas naturais. São Paulo: Fepaf; 2003. p. 91-110.         [ Links ]

Reis A, Três DR, Scariot EC. Restauração na floresta ombrófila mista através da sucessão natural. Pesq Flor Bras. 2007; 55: 67-73.         [ Links ]

Ryan PR, DiTomaso JM, Kochian LV. Aluminium toxicity in roots: an investigation of spatial sensitivity and The role of the root cap. J Exp Bot. 1993; 44: 437-446.         [ Links ]

Rodrigues BD, Martins SV, Leite HG. Avaliação do potencial da transposição da serapilheira e do banco de sementes do solo para restauração florestal em áreas degradadas. Rev Árvore. 2010; 34 (1): 65-73.         [ Links ]

Sávio FB, Maranho LT. Implantação e avaliação de ecotecnologia utilizando fibra de coco na restauração de áreas degradadas. In: Anais VII Simpósio Nacional sobre Recuperação de Áreas Degradadas; 2008 oct; Curitiba, Brazil. Curitiba: Sociedade Brasileira de Recuperação de Áreas Degradadas (SOBRADE); UFPR; 2008. p. 247-265.         [ Links ]

Schorn LA, Krieger A, Nadolny MC, Fenilli TAB. Avaliação de Técnicas para Indução de Regeneração Natural em Área de Preservação Permanente sob Uso Anterior do Solo com Pinus eliotti. Floresta. 2010; 40 (2): 281-294.         [ Links ]

Society for Ecological Restoration International Science & Policy Working Group. The SER International Primer on Ecological Restoration. [updated 2012 Out 1; cited 2012 Out 1]. Available from: <http://www.ser.org & Tucson: Society for Ecological Restoration International. 2004.         [ Links ]

Statsoft. Statistica for windows: computer program manual. Version 6.0. Tulsa: StatSoft, 2002.         [ Links ]

Viani RAG, Rodrigues RR. Potencial da comunidade de plântulas de um fragmento florestal para a restauração de florestas tropicais. Sci Agric. 2009; 66 (6): 772-779.         [ Links ]

Wikum DA, Shanholtzer GF. Application of the braun-blanquet cover-abundance scale for vegetation analysis in land development studies. Environ Manage. 1978; 2 (4): 323-329.         [ Links ]

 

 

Received: November 09, 2012
Accepted: December 23, 2013

 

 

* Author for correspondence: maranho@up.com.br

Creative Commons License All the contents of this journal, except where otherwise noted, is licensed under a Creative Commons Attribution License