Contribution of <i>Pseudobombax</i> aff. <i>petropolitanum</i> to Nutrient Cycling in Woody Vegetation from a Neotropical Inselberg

Freitas, Carlos Antônio Araújo de; Souza, Rodrigo Camara de; Pereira, Marcos Gervasio; Caldeira, Marcos Vinicius Winckler; Couto, Dayvid Rodrigues; Kunz, Sustanis Horn; Moreau, Julia Siqueira; Dias, Henrique Machado; Momolli, Dione Richer

doi:10.1590/2179-8087-FLORAM-2022-0034

Abstract

The aim of the study was to investigate Pseudobombax aff. petropolitanum (PP) contribution on annual fine litterfall, carbon content, and nutrient concentration, compared to other woody species (OS) on a neotropical inselberg in Espírito Santo state, Brazil. Annual fine litterfall was systematic monthly collected (November 2011-October 2012) by means of 15 littertraps (0.25 m²) placed in five transects, oven-dried (65 °C, 72 h), weighed, and C content and nutrients concentration (N, P, K, Ca, Mg, S, B, Cu, Fe, Mn, Zn) were estimated. PP performed lower litterfall, C content, and nutrient concentration excepting higher K concentration, compared to OS. The results suggested that PP performed higher nutrient conservation, which indicated its potential in restoring degraded areas observed in the inselberg.

Keywords:
Atlantic Forest; ecosystem functioning; litterfall; rocky outcrop; rupestrian ecosystem

1. INTRODUCTION AND OBJECTIVES

Inselbergs are Precambrian granitic and gneissic rocky outcrops, usually monolithic and are critical spots for conservation of plant diversity (Porembski, 2007Porembski S. (2007) Tropical inselbergs: habitat types, adaptive strategies and diversity patterns. Brazilian Journal of Botany 2007; 30: 579-86.; Hopper et al., 2016Hopper SD, Silveira FAO, Fiedler PL. Biodiversity hotspots and Ocbil theory. Plant and Soil 2016; 403: 167-216.). In southeastern Brazil, inselbergs within the Atlantic Rainforest biome represent a global hotspot of rupicolous plants, whose beta diversity, i.e., species turnover between individual inselbergs, is unusually high due to high degree of habitat specialization even when comparing inselbergs in the same region that increase as the geographical distance increases (Porembski, 2007Porembski S. (2007) Tropical inselbergs: habitat types, adaptive strategies and diversity patterns. Brazilian Journal of Botany 2007; 30: 579-86.; Couto et al., 2016Couto DR, Dias HM, Pereira MCA, Fraga CN, Pezzopane JEM. Vascular epiphytes on Pseudobombax (Malvaceae) in rocky outcrops (inselbergs) in Brazilian Atlantic Rainforest: basis for conservation of a threatened ecosystem. Rodriguésia 2016; 67(3): 583-601.; Pinto-Junior et al., 2020Pinto-Junior HV, Villa PM, Pereira MCA, Menezes LFT. The pattern of high plant diversity of Neotropical inselbergs: highlighting endemic, threatened and unique species. Acta Botanica Brasilica 2020; 34(4): 645-661.).

In general, soils on inselbergs are poorly developed, shallow, highly susceptible to leaching, and characterized by coarse sandy texture, high levels of exchangeable aluminum, low nutritional quality, and variable levels of organic matter (Benites et al., 2007Benites VM, Schaefer CEGR, Simas FNB, Santos HG. Soils associated with rock outcrops in the Brazilian mountain ranges Mantiqueira and Espinhaço. Revista Brasileira de Botânica 2007;30(4): 569-577.).

The development of different types of plant communities on inselbergs (see Porembski 2007Porembski S. (2007) Tropical inselbergs: habitat types, adaptive strategies and diversity patterns. Brazilian Journal of Botany 2007; 30: 579-86.), which includes woody vegetation characterized by high light demands, presence of low trees and shrubs, adapted to shallow soils and with poor water and nutrients retention (Francisco et al., 2018Francisco TM, Couto DR, Evans DM, Garbin ML, Ruiz-Miranda CR. Structure and robustness of an epiphyte-phorophyte commensalistic network in a neotropical inselberg. Austral Ecology 2018; 43(8):903-914.; Couto et al., 2022Couto DR, Francisco TM, Nascimento MT. Commensalistic epiphyte-phorophyte networks in woody vegetation of tropical inselbergs: Patterns of organization and structure. Austral Ecology 2022, 47: 911-927.) naturally depends, among other factors, on nutrient cycling.

Nutrient cycling is an important soil entry route for nutrients derived from senescent plant material, and studies have focused on litterfall and its nutrient concentration in forest ecosystems, such as Ombrophilous Forest (Bianchin et al., 2017Bianchin JE, Marques R, Blum H, Oliva EV, Donha CG, Silveira FM et al. Micronutrientes na serapilheira depositada em florestas secundárias no litoral do Paraná. Nativa 2017; 5(6):446-455.; Camara et al., 2018aCamara R, Silva VD, Delaqua GCG, Lisbôa CP, Villela DM. Relação entre sucessão secundária, solo e serapilheira em uma Reserva Biológica no estado do Rio de Janeiro, Brasil. Ciência Florestal 2018a; 28(2): 674-686.; 2018bCamara R, Pereira MG, Menezes LFT, Segall AB, Castro JSR. Litter dynamics in a forest dune at Restinga da Marambaia, RJ, Brazil. Floresta e Ambiente 2018b; 25(2): e20160046.), Semideciduous Forest (Scheer et al., 2011Scheer MB, Gatti G, Wisniewski C. Nutrient fluxes in litterfall of a secondary successional Alluvial Rain Forest in Southern Brazil. Revista de Biología Tropical 2011; 59(4): 1869-1882; Machado et al., 2018Machado MR, Souza RC, Calvi GP, Piña-Rodrigues FCM, Leles PSS. Litterfall: a bio-indicator for edge effect in a Semi-deciduous Seasonal Forest. Floresta e Ambiente 2018; 25(3): e20170528.; Carvalho et al., 2019Carvalho FF, Barreto-Garcia PAB, Aragão MA, Virgens AP. Litterfall and litter decomposition in Pinus and native forests. Floresta e Ambiente 2019; 26(3): e20170165.; Dick & Schumacher, 2020Dick G, Schumacher MV. Litterfall in the Semideciduous Seasonal Forest in southern Brazil. Floresta e Ambiente 2020; 27(2): e20180298.; Menezes et al., 2020Menezes LFT, Souza RC, Pereira MG, Pires FP, Fanticelle BS, Araujo-Filho PB. Different patterns of nutrient cycling in contiguous phytophysiognomies of Atlantic Forest, Brazil. Floresta e Ambiente 2020; 27(1): e20190045; Câmara et al., 2021Câmara YB, Holanda AC, Costa EJP. Aporte de serapilheira na borda de fragmentos florestais em diferentes estágios sucessionais na Mata Atlântica do Rio Grande do Norte, Brasil. Madera y Bosques 2021; 27(2): e2722179.; Lagemann et al., 2022Lagemann MP, Vogel HLM, Vieira FCB, Lorentz LH, Schumacher MV, Dick G. Leaf litterfall, decomposition and nutrients release in a Seasonal Semideciduous Forest in Southern Brazil. Ecologia e Nutrição Florestal 2022; 10: e02.), and Deciduous Forest (Schumacher et al., 2018Schumacher MV, Szymczak DA, Trüby P, Londero EK, Marafiga J. Aporte de serapilheira e nutrientes em uma Floresta Estacional Decidual na região central do Rio Grande do Sul. Ciência Florestal 2018; 28(2): 532-541.; Araújo et al., 2020Araújo VFP, Barbosa MRV, Araújo JP, Vasconcellos A. Spatial-temporal variation in litterfall in seasonally dry tropical forests in Northeastern Brazil. Brazilian Journal of Biology 2020; 80(2): 273-284.). Regardless of the forest typology being subject to greater or lesser seasonality, climate conditions influence nutrient cycling (Scheer et al., 2011Scheer MB, Gatti G, Wisniewski C. Nutrient fluxes in litterfall of a secondary successional Alluvial Rain Forest in Southern Brazil. Revista de Biología Tropical 2011; 59(4): 1869-1882; Bianchin et al., 2017Bianchin JE, Marques R, Blum H, Oliva EV, Donha CG, Silveira FM et al. Micronutrientes na serapilheira depositada em florestas secundárias no litoral do Paraná. Nativa 2017; 5(6):446-455.; Dick & Schumacher, 2020Dick G, Schumacher MV. Litterfall in the Semideciduous Seasonal Forest in southern Brazil. Floresta e Ambiente 2020; 27(2): e20180298.).

However, these relevant key issues for the general understanding of inselberg functioning besides studies on C stock estimates, have been neglected, with only one published study focusing on accumulation of litter on topsoil and its nutrient concentration (Freitas et al., 2015Freitas CAA, Caldeira MVW, Horn SK, Castro KC, Viera M. Serapilheira acumulada em Complexo Rupestre de Granito, Mimoso do Sul, ES. Revista Árvore 2015; 39(4):671-681.). Furthermore, such research can support the development of strategies aimed at the management, conservation, and restoration of degraded areas, especially by mined land, commonly found in Espírito Santo (Couto et al., 2017Couto DR, Francisco TM, Manhães VC, Dias HM, Pereira MCA. Floristic composition of a Neotropical inselberg from Espírito Santo state, Brazil: an important area for conservation. Check List 2017; 13(1):1-12.), besides deforestation, induced fires, and uncontrolled tourism (Benites et al., 2007Benites VM, Schaefer CEGR, Simas FNB, Santos HG. Soils associated with rock outcrops in the Brazilian mountain ranges Mantiqueira and Espinhaço. Revista Brasileira de Botânica 2007;30(4): 569-577.).

Generally, a high abundance of a particular species is an indication of its nutrient cycling efficiency, a necessary characteristic for the sustainable development of ecosystems. Studies reported a high abundance of the lithophytic endemic Pseudobombax aff. petropolitanum A.Robyns (Malvaceae: Bombacoideae) in woody inselberg vegetation at Atlantic Forest of Espírito Santo state (Couto et al., 2017Couto DR, Francisco TM, Manhães VC, Dias HM, Pereira MCA. Floristic composition of a Neotropical inselberg from Espírito Santo state, Brazil: an important area for conservation. Check List 2017; 13(1):1-12., 2019, 2022; Francisco et al., 2018Francisco TM, Couto DR, Evans DM, Garbin ML, Ruiz-Miranda CR. Structure and robustness of an epiphyte-phorophyte commensalistic network in a neotropical inselberg. Austral Ecology 2018; 43(8):903-914.), from now on, PP. The PP is endemic to inselbergs of Rio de Janeiro and Espírito Santo States (Carvalho-Sobrinho & Yoshikawa 2022Carvalho-Sobrinho JG, Yoshikawa VN. Pseudobombax in Flora e Funga do Brasil. Jardim Botânico do Rio de Janeiro. Disponível em: <Disponível em: https://floradobrasil.jbrj.gov.br/FB603542 >. (Acesso em: 08 set. 2022)
https://floradobrasil.jbrj.gov.br/FB6035... ), and functions as a nucleus of biodiversity expansion in this ecosystem (Couto et al., 2016Couto DR, Dias HM, Pereira MCA, Fraga CN, Pezzopane JEM. Vascular epiphytes on Pseudobombax (Malvaceae) in rocky outcrops (inselbergs) in Brazilian Atlantic Rainforest: basis for conservation of a threatened ecosystem. Rodriguésia 2016; 67(3): 583-601., 2017Couto DR, Francisco TM, Manhães VC, Dias HM, Pereira MCA. Floristic composition of a Neotropical inselberg from Espírito Santo state, Brazil: an important area for conservation. Check List 2017; 13(1):1-12., 2019Couto DR, Francisco TM, Garbin ML, Dias HM, Pereira MCA, Menini Neto L, Pezzopane JEM. Surface roots as a new ecological zone for occurrence of vascular epiphytes: a case study on Pseudobombax trees on inselbergs. Plant Ecology 2019; 220(11):1071-1084., 2022Couto DR, Francisco TM, Nascimento MT. Commensalistic epiphyte-phorophyte networks in woody vegetation of tropical inselbergs: Patterns of organization and structure. Austral Ecology 2022, 47: 911-927.; Francisco et al., 2018Francisco TM, Couto DR, Evans DM, Garbin ML, Ruiz-Miranda CR. Structure and robustness of an epiphyte-phorophyte commensalistic network in a neotropical inselberg. Austral Ecology 2018; 43(8):903-914.). In the municipality of Mimoso do Sul, Espírito Santo, 105 species of vascular epiphytes were observed colonizing thick and exposed roots on the rocky surface and horizontal branches of PP, which can reach a height of 15 m (Couto et al., 2016Couto DR, Dias HM, Pereira MCA, Fraga CN, Pezzopane JEM. Vascular epiphytes on Pseudobombax (Malvaceae) in rocky outcrops (inselbergs) in Brazilian Atlantic Rainforest: basis for conservation of a threatened ecosystem. Rodriguésia 2016; 67(3): 583-601., 2019Couto DR, Francisco TM, Garbin ML, Dias HM, Pereira MCA, Menini Neto L, Pezzopane JEM. Surface roots as a new ecological zone for occurrence of vascular epiphytes: a case study on Pseudobombax trees on inselbergs. Plant Ecology 2019; 220(11):1071-1084.), with one single PP individual contributed 46 % of the total wealth of the epiphytic community (Francisco et al., 2018Francisco TM, Couto DR, Evans DM, Garbin ML, Ruiz-Miranda CR. Structure and robustness of an epiphyte-phorophyte commensalistic network in a neotropical inselberg. Austral Ecology 2018; 43(8):903-914.).

This study provides important contributions to the understanding of the dynamics of fine litterfall and nutrients concentration by woody vegetation on a neotropical inselberg. This study aimed to investigate PP contribution on annual fine litterfall, carbon content, and nutrient concentration, compared to other woody species (OS) on a neotropical inselberg in Espírito Santo state, Brazil. We tested the hypothesis that the local abundance of PP is a function of adaptative mechanisms such as low litterfall and low nutrient concentration due to high nutrient conservation.

2. MATERIALS AND METHODS

This study was conducted in an area of inselberg woody vegetation on an ancient relief, naturally isolated landform, with very shallow soil, classified as humic Litholic Neosol, currently surrounded by forest fragments (Montane Seasonal Semideciduous and Dense Ombrophilous Forests), agricultural crops, mainly Coffea arabica L., and threatened by the ornamental stone mining industry (Couto et al., 2016Couto DR, Dias HM, Pereira MCA, Fraga CN, Pezzopane JEM. Vascular epiphytes on Pseudobombax (Malvaceae) in rocky outcrops (inselbergs) in Brazilian Atlantic Rainforest: basis for conservation of a threatened ecosystem. Rodriguésia 2016; 67(3): 583-601., 2017Couto DR, Francisco TM, Manhães VC, Dias HM, Pereira MCA. Floristic composition of a Neotropical inselberg from Espírito Santo state, Brazil: an important area for conservation. Check List 2017; 13(1):1-12., 2019Couto DR, Francisco TM, Garbin ML, Dias HM, Pereira MCA, Menini Neto L, Pezzopane JEM. Surface roots as a new ecological zone for occurrence of vascular epiphytes: a case study on Pseudobombax trees on inselbergs. Plant Ecology 2019; 220(11):1071-1084.). The montane inselberg is locally known as “Afloramento do Toti” (20°56'18"S 41°32'38"W), which covers an area of about 2.5 ha at elevations ranging from 700 to 780 m a.s.l. on Pedra dos Pontões, municipality of Mimoso do Sul, Espírito Santo State, Brazil (Figure 1A, 1B, and 1C).

Figure 1
Location of the study area in relation to South America, Brazil, Espírito Santo State (A), and municipality of Mimoso do Sul (B). Field photograph of inselberg woody vegetation (C) and Pseudobombax aff. petropolitanum flowering (D). Photos by Dayvid R. Couto.

Pedra dos Pontões has a high richness and diversity of endemic endangered species, besides low similarity in terms of floristic composition when compared to other inselbergs in state (Couto et al., 2017Couto DR, Francisco TM, Manhães VC, Dias HM, Pereira MCA. Floristic composition of a Neotropical inselberg from Espírito Santo state, Brazil: an important area for conservation. Check List 2017; 13(1):1-12.; Pinto-Junior et al., 2020Pinto-Junior HV, Villa PM, Pereira MCA, Menezes LFT. The pattern of high plant diversity of Neotropical inselbergs: highlighting endemic, threatened and unique species. Acta Botanica Brasilica 2020; 34(4): 645-661.), for which it has been recognized as a priority conservation area (Couto et al., 2016Couto DR, Dias HM, Pereira MCA, Fraga CN, Pezzopane JEM. Vascular epiphytes on Pseudobombax (Malvaceae) in rocky outcrops (inselbergs) in Brazilian Atlantic Rainforest: basis for conservation of a threatened ecosystem. Rodriguésia 2016; 67(3): 583-601., 2017Couto DR, Francisco TM, Manhães VC, Dias HM, Pereira MCA. Floristic composition of a Neotropical inselberg from Espírito Santo state, Brazil: an important area for conservation. Check List 2017; 13(1):1-12.). The inselberg woody vegetation has a prominent presence of sparse stands of PP (Figure 1D), with some tall individuals for the area (average height of 7.7 m ± 3.3 and average diameter at breast height of 46.4 cm ± 31.9), forming small groups in some cases (Couto et al., 2016Couto DR, Dias HM, Pereira MCA, Fraga CN, Pezzopane JEM. Vascular epiphytes on Pseudobombax (Malvaceae) in rocky outcrops (inselbergs) in Brazilian Atlantic Rainforest: basis for conservation of a threatened ecosystem. Rodriguésia 2016; 67(3): 583-601.).

For the physical-chemical characterization of the soil, a total of 20 samples were collected, at a depth of 10 cm, four per transect. The samples were homogenized, and the air-dried fine earth prepared in the laboratory. We proceeded to the followed soil analyzes (Silva, 2009Silva FC. Manual de análises químicas de solos, plantas e fertilizantes. 2ª ed. Brasília: Embrapa Informação Tecnológica, 2009.): pH (in water - 1:2.5 ratio) was 4.5, the concentrations of P, K, and Na were 32, 76, and 7 mg dm^-3, respectively, the concentrations of exchangeable Ca, Mg, Al, and H+Al were 0.5, 0.3, 1.4, and 12.8 cmol_c dm^-3, respectively, the concentrations of exchangeable Fe, Cu, Zn, and Mn were 44, 0.2, 1.6, and 5 mg dm^-3, respectively. The effective Cation Exchange Capacity (CEC) was 2.4, the CEC pH 7 was 13.8, the sum of bases was 1 cmol_c dm^-3, the base saturation index was 7.4, and aluminum saturation index was 57.1 %.

According to the Köppen classification, the climate of the study area is Cwb, characterized by cold and dry winters and wet summers (Alvares et al., 2013Alvares CA, Stape JL, Sentelhas PC, Gonçalves JLM, Sparovek G. Köppen’s climate classification map for Brazil. Meteorologische Zeitschrift 2013; 22(6): 711-728.). Climatic data during the study period (from November 2011 to October 2012), were collected by the Alegre Meteorological Station which is situated at a straight-line distance of 18 km from the study site and obtained from the National Institute of Meteorology website. In this period, the monthly average temperature varied from 20.3 ºC (August, winter) to 26.8 ºC (February, summer), and the accumulated precipitation varied from 10.2 mm (July, winter) to 258.2 mm (December, summer) (Figure 2).

Figure 2
Monthly accumulated precipitation and mean temperature from November/2011 to October/2012, in Mimoso do Sul, Espírito Santo State, Brazil. Source: National Institute of Meteorology website. Spring (SP), Summer (SU), Autumn (AU), Winter (WI).

The annual accumulated precipitation and mean annual temperature were 1,038.80 mm and 23.5 °C, respectively (Figure 2). The maximum accumulated precipitation (approximately 445.0 mm) was registered in summer, intermediate values (260.6 mm and 245.2 mm) were observed in spring and autumn, respectively, and the minimum value (88.0 mm) in winter. The highest average temperature (approximately 25.7 °C) was verified in summer, followed by intermediate values registered in autumn and spring (23.8 °C and 23.4 °C, respectively), and the lowest value (21.1 °C) in winter.

Fine litterfall was systematic monthly collected from November 2011 to October 2012 along five transects (2 m × 50 m) spaced 10 m apart from each other on the northeastern slope of the inselberg. In each transect (pseudo-replicate) were placed five 0.70 m high wooden frames measuring 0.50 m × 0.50 m (0.25 m²), with a 2 mm mesh nylon screen at the bottom, approximately 25 m apart from each other, totaling 15 collectors.

All collected material was stored in plastic bags. At the laboratory, the material was transferred to paper bags, dried in an air-circulating oven (65 °C, 72 h), individualized into the fractions: (i) litterfall from PP and (ii) litterfall from OS (sensuFrancisco et al., 2018Francisco TM, Couto DR, Evans DM, Garbin ML, Ruiz-Miranda CR. Structure and robustness of an epiphyte-phorophyte commensalistic network in a neotropical inselberg. Austral Ecology 2018; 43(8):903-914.), and weighed to the nearest 0.01 g on a precision balance to obtain the litterfall dry biomass (kg ha⁻¹). OS included the terrestrial/hemiepiphyte species Oreopanax capitatus (Jacq.) Decne. & Planch. (Araliaceae), terrestrial/rupicolous species Clusia mexiae P.F.Stevens (Clusiaceae), Eremanthus crotonoides (DC.) Sch. Bip. (Asteraceae), Eugenia brasiliensis Lam. (Myrtaceae), Guapira opposita (Vell.) Reitz (Nyctaginaceae), Handroanthus sp. (Bignoniaceae), the terrestrial species Croton floribundus Spreng. (Euphorbiaceae) and Vernonanthura polyanthes (Sprengel) Vega & Dematteis (Asteraceae). Both fractions include the respective leaves, branches, reproductive structures (flowers, fruits, seeds), bark, and other plant residues.

Subsequently, samples were ground in a Wiley-type mill and stored in plastic bottles. Samples from three transects were randomly chosen monthly and subjected to analyses of macronutrient (N, P, K, Ca, Mg, and S) and micronutrient (B, Cu, Fe, Mn, and Zn) concentration (g kg^-1 and mg kg^-1, respectively) (Tedesco et al., 1995Tedesco MJ, Gianello C, Bissani CA, Bohnen H, Volkweis SJ. Análise de solo, plantas e outros materiais. 2ª ed. Porto Alegre: Universidade Federal do Rio Grande do Sul; 1995.; Miyazawa et al., 1999Miyazawa M, Pavan MA, Muraoka T, Carmo CAFS, Mello WJ. Análises químicas de tecido vegetal. In: Silva FC, editor. Manual de análises químicas de solos, plantas e fertilizantes. Rio de Janeiro: Embrapa Solos; 1999.). B was extracted by dry digestion and the other nutrients by wet digestion. N concentration was determined by the Kjeldahl method; P, S, and B concentrations by UV-Vis spectrophotometry; and K, Ca, Mg, Cu, Fe, Mn, and Zn concentrations by atomic absorption spectrophotometry. We considered C content is 47.0 % of the dry necromass (Martinelli et al., 2017Martinelli LA, Lins SEM, Santos-Silva JC. Fine litterfall in the Brazilian Atlantic Forest. Biotropica 2017; 49(4): 443-451. ).

The data were individualized in seasons (spring: September, October, and November; summer: December, January, and February; autumn: March, April, and May; winter: June, July, and August), following the methodology of other studies (Bianchin et al., 2017Bianchin JE, Marques R, Blum H, Oliva EV, Donha CG, Silveira FM et al. Micronutrientes na serapilheira depositada em florestas secundárias no litoral do Paraná. Nativa 2017; 5(6):446-455.). The interaction effects between season (spring, summer, autumn, winter) and litterfall fraction (PP, OS) were investigated within five pseudo-replicates for both litterfall and C content, and three pseudo-replicates for nutrient concentration.

Data were subjected to Repeated Measures Analysis of Variance (ANOVA), in which sampling periods (four seasons; within-subjects factor or within effects) and litterfall fractions (between-subjects factor or between effects) were considered as sources of variation. To evaluate the isolated effects of litterfall fraction on the variables, the homogeneity of variance was tested by Levene’s test. When homoscedasticity assumptions were met, means were compared by the parametric Fisher’s least significant difference test; otherwise, means were compared by the nonparametric Mann-Whitney U-test. Those univariate analyses were performed using Statistica version 8.0 (StatSoft, Inc., Dell, Tulsa, USA) considering P < 0.05 as significant.

Multivariate analyzes were also performed, using the PAST software version 2.17c, to carry out a global analysis in which all variables were considered. In this sense, the principal component analysis allows the recognition of association between the litterfall fractions within seasons and a large set of variables, while the hierarchical clustering by using the Gower coefficient allows to identify dissimilarities between de litterfall fractions within the seasons.

3. RESULTS

Litterfall occurred throughout the annual period, with maximum monthly values in March 2012 (autumn) for both fractions (PP: 575.20 ± 270.96 kg ha⁻¹, OS: 721.49 ± 209.52 kg ha⁻¹) and total litterfall (1,296.69 ± 182.73 kg ha⁻¹) (Figure 3).

Figure 3
Monthly seasonality of litterfall from Pseudobombax aff. petropolitanum (PP), other woody species (OS), and total litterfall (TL) on a neotropical inselberg in Espírito Santo State, Brazil, from November 2011 to October 2012. The vertical bars in the graph indicate the standard deviation. Spring (SP), Summer (SU), Autumn (AU), Winter (WI).

The interaction between litterfall fraction and season significantly affected litterfall and contents of C (P = 0.0360, for both variables), concentrations of N, P, K, Ca, Mg, B, Cu, Fe, Mn, Zn (P = 0.0000, for these ten variables), and S (P = 0.0002). There were no significant differences between the litterfall fractions, regarding litterfall and C content in autumn and winter, concentration of K in spring, Mg in summer, both P and S in winter (Tables 1 and 2).

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Table 1
Seasonal and annual values of litterfall and carbon content from Pseudobombax aff. petropolitanum (PP), other woody species (OS), and total litterfall (TL) on a neotropical inselberg in Espírito Santo State, Brazil, from November 2011 to October 2012¹.

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Table 2
Seasonal and annual macronutrient concentration from Pseudobombax aff. petropolitanum (PP), other woody species (OS), and total litterfall (TL) on a neotropical inselberg in Espírito Santo State, Brazil, from November 2011 to October 2012¹.

Despite this, there were two patterns of results for the effect of the litterfall fraction. The first one, which was the most frequent, refers to significantly higher litterfall and C content in spring, summer, and annual period, besides concentration of N, Ca, B, Fe, Mn, and Zn in the four seasons and annual period, P, S and Cu, in spring, summer, autumn, and annual period, Mg in spring, autumn, and annual period nutrient in litterfall from OS (Tables 1, 2, and 3).

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Table 3
Seasonal and annual micronutrient concentration from Pseudobombax aff. petropolitanum (PP), other woody species (OS), and total litterfall (TL) on a neotropical inselberg in Espírito Santo State, Brazil, from November 2011 to October 2012¹.

The second pattern indicated the opposite response, that is, significantly higher values in litterfall from PP, that was recorded for K concentration in summer, autumn, winter, and annual period, Mg and Cu in winter (Tables 2 and 3).

Litterfall from PP presented negative eigenvectors, whereas litterfall from OS presented positive eigenvectors, due to the position in the left portion and right portion of the Principal Component 1, respectively (Figure 4A). Principal Component Analysis explained approximately 76.0 % of the variability in the original variables, most of which was explained by Principal Component 1, when compared to Principal Component 2 (Table 4).

Figure 4
Ordering and classification diagrams resulting from multivariate analysis of principal components (A) and hierarchical clustering (B) considering litterfall (LTF), nutrient concentration (CC) from Pseudobombax aff. petropolitanum (PP) and other woody species (OS), on a neotropical inselberg in Espírito Santo State, Brazil, from November 2011 to October 2012. Spring (SP), Summer (SU), Autumn (AU), Winter (WI).

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Table 4
Eigenvector of litterfall (LTF), carbon content (CT), and nutrient concentration (CC) from Pseudobombax aff. petropolitanum (PP) and other woody species (OS), on a neotropical inselberg in Espírito Santo State, Brazil, from November 2011 to October 2012, in Principal Components (PC) 1 and 2 from the multivariate Principal Components Analysis.

Litterfall from OS was associated with maximum mean values of all variables analyzed, except for K concentration, whose maximum mean value was associated with litterfall from PP (Figure 4A). The eigenvector of N, S, and Mn concentration presented the higher influence on the Principal Component 1, due to the higher values of correlation coefficient (> 0.90) (Table 4). Nonetheless, the eigenvector of P, Ca, B, and Cu concentration also presented significant correlation coefficient values (> 0.70) with the Principal Component 1 (Table 4). The eigenvector of none of the analyzed variables showed significant correlation coefficient values (> 0.70) with the Principal Component 2.

The vectors of N, P, S, Cu, Fe, and Mn concentration were positioned in the same direction and formed acute angles between them (high correlation between them) (Figure 4A). The same pattern was verified for the vectors of Ca and Mg concentration, while the vectors of litterfall and C content variables overlapped.

The hierarchical cluster analysis pointed to the dissimilarity between the litterfall fractions. In fact, litterfall from PP within the seasons grouped by a dissimilarity distance of approximately 0.52 (or 52.0 %), in relation to the litterfall from OS (Figure 4B).

4. DISCUSSION

The continuous fine litterfall throughout the year in the inselberg woody vegetation, although seasonality is observed in this process, is a phenomenon commonly observed in the Atlantic Forest biome, regardless of phytophysiognomy, successional stage, altitude, and distance from the edge towards the interior of plant community (Martinelli et al., 2017Martinelli LA, Lins SEM, Santos-Silva JC. Fine litterfall in the Brazilian Atlantic Forest. Biotropica 2017; 49(4): 443-451. ; Sousa-Neto et al., 2017Sousa-Neto E, Lins S, Martins S, Piccolo M, Ferreira M, Camargo P et al. Litterfall mass and nutrient fluxes over an altitudinal gradient in the coastal Atlantic Forest, Brazil. Journal of Tropical Ecology 2017; 33(4): 261-269.; Camara et al., 2018aCamara R, Silva VD, Delaqua GCG, Lisbôa CP, Villela DM. Relação entre sucessão secundária, solo e serapilheira em uma Reserva Biológica no estado do Rio de Janeiro, Brasil. Ciência Florestal 2018a; 28(2): 674-686., 2018bCamara R, Pereira MG, Menezes LFT, Segall AB, Castro JSR. Litter dynamics in a forest dune at Restinga da Marambaia, RJ, Brazil. Floresta e Ambiente 2018b; 25(2): e20160046.; Machado et al., 2018Machado MR, Souza RC, Calvi GP, Piña-Rodrigues FCM, Leles PSS. Litterfall: a bio-indicator for edge effect in a Semi-deciduous Seasonal Forest. Floresta e Ambiente 2018; 25(3): e20170528.; Schumacher et al., 2018Schumacher MV, Szymczak DA, Trüby P, Londero EK, Marafiga J. Aporte de serapilheira e nutrientes em uma Floresta Estacional Decidual na região central do Rio Grande do Sul. Ciência Florestal 2018; 28(2): 532-541.; Carvalho et al., 2019Carvalho FF, Barreto-Garcia PAB, Aragão MA, Virgens AP. Litterfall and litter decomposition in Pinus and native forests. Floresta e Ambiente 2019; 26(3): e20170165.; Araújo et al., 2020Araújo VFP, Barbosa MRV, Araújo JP, Vasconcellos A. Spatial-temporal variation in litterfall in seasonally dry tropical forests in Northeastern Brazil. Brazilian Journal of Biology 2020; 80(2): 273-284.; Dick & Schumacher, 2020Dick G, Schumacher MV. Litterfall in the Semideciduous Seasonal Forest in southern Brazil. Floresta e Ambiente 2020; 27(2): e20180298.; Menezes et al., 2020Menezes LFT, Souza RC, Pereira MG, Pires FP, Fanticelle BS, Araujo-Filho PB. Different patterns of nutrient cycling in contiguous phytophysiognomies of Atlantic Forest, Brazil. Floresta e Ambiente 2020; 27(1): e20190045; Câmara et al., 2021Câmara YB, Holanda AC, Costa EJP. Aporte de serapilheira na borda de fragmentos florestais em diferentes estágios sucessionais na Mata Atlântica do Rio Grande do Norte, Brasil. Madera y Bosques 2021; 27(2): e2722179.; Lagemann et al., 2022Lagemann MP, Vogel HLM, Vieira FCB, Lorentz LH, Schumacher MV, Dick G. Leaf litterfall, decomposition and nutrients release in a Seasonal Semideciduous Forest in Southern Brazil. Ecologia e Nutrição Florestal 2022; 10: e02.). The maximum monthly litterfall in inselberg (PP, OS, total litterfall) verified in March 2012 (end of the rainy season and beginning of the dry season) was probable a function of low accumulated precipitation, which was only 74.40 mm (approximately 7.2 % of annual precipitation). The accumulated precipitation in the previous month (February) was even lower (17.40 mm) for the summer. Therefore, the extremely low rainfall in the previous month also impacted the maximum litterfall in the following month.

The inselberg is surrounded by fragments of Dense Ombrophilous Forest and Seasonal Semideciduous Forest. However, the maximum litterfall in response to low precipitation approached what is commonly found in Seasonal Semideciduous Forest areas, as a mechanism for decreasing evapotranspiration with leaf fall, the main component of litterfall, in periods of lower precipitation and soil water availability (Carvalho et al., 2019Carvalho FF, Barreto-Garcia PAB, Aragão MA, Virgens AP. Litterfall and litter decomposition in Pinus and native forests. Floresta e Ambiente 2019; 26(3): e20170165.; Dick & Schumacher, 2020Dick G, Schumacher MV. Litterfall in the Semideciduous Seasonal Forest in southern Brazil. Floresta e Ambiente 2020; 27(2): e20180298.; Câmara et al., 2021Câmara YB, Holanda AC, Costa EJP. Aporte de serapilheira na borda de fragmentos florestais em diferentes estágios sucessionais na Mata Atlântica do Rio Grande do Norte, Brasil. Madera y Bosques 2021; 27(2): e2722179.; Lagemann et al., 2022Lagemann MP, Vogel HLM, Vieira FCB, Lorentz LH, Schumacher MV, Dick G. Leaf litterfall, decomposition and nutrients release in a Seasonal Semideciduous Forest in Southern Brazil. Ecologia e Nutrição Florestal 2022; 10: e02.). This pattern is also verified in Deciduous Forest (Schumacher et al., 2018Schumacher MV, Szymczak DA, Trüby P, Londero EK, Marafiga J. Aporte de serapilheira e nutrientes em uma Floresta Estacional Decidual na região central do Rio Grande do Sul. Ciência Florestal 2018; 28(2): 532-541.; Araújo et al., 2020Araújo VFP, Barbosa MRV, Araújo JP, Vasconcellos A. Spatial-temporal variation in litterfall in seasonally dry tropical forests in Northeastern Brazil. Brazilian Journal of Biology 2020; 80(2): 273-284.), in contrast to evergreen forests where maximum litterfall is usually observed in the wet season (Sousa-Neto et al., 2017Sousa-Neto E, Lins S, Martins S, Piccolo M, Ferreira M, Camargo P et al. Litterfall mass and nutrient fluxes over an altitudinal gradient in the coastal Atlantic Forest, Brazil. Journal of Tropical Ecology 2017; 33(4): 261-269.; Camara et al., 2018aCamara R, Silva VD, Delaqua GCG, Lisbôa CP, Villela DM. Relação entre sucessão secundária, solo e serapilheira em uma Reserva Biológica no estado do Rio de Janeiro, Brasil. Ciência Florestal 2018a; 28(2): 674-686., 2018bCamara R, Pereira MG, Menezes LFT, Segall AB, Castro JSR. Litter dynamics in a forest dune at Restinga da Marambaia, RJ, Brazil. Floresta e Ambiente 2018b; 25(2): e20160046.).

Total annual fine litterfall and its carbon content in inselberg (approximately 5.41 Mg ha^-1 year^-1 and 2.54 Mg ha^-1 year^-1, respectively) were both the same for the average in South American tropical forests that grow in white sand and poor soils (Chave et al., 2010Chave J, Navarrete D, Almeida S, Álvarez E, Aragão LEOC, Bonal D et al. Regional and seasonal patterns of litterfall in tropical South America. Biogeosciences 2010; 7(1): 43-55.), but lower than the average obtained from 105 estimates from 45 sites in the Atlantic Forest biome in Brazil (8.0 Mg ha^-1 year^-1 and carbon content 3.76 Mg ha^-1 year^-1), which included secondary and old growth fragments from both seasonal and evergreen forests (Martinelli et al., 2017Martinelli LA, Lins SEM, Santos-Silva JC. Fine litterfall in the Brazilian Atlantic Forest. Biotropica 2017; 49(4): 443-451. ). This pattern is due to the low primary productivity caused by soil nutritional deficiency on inselbergs (Benites et al., 2007Benites VM, Schaefer CEGR, Simas FNB, Santos HG. Soils associated with rock outcrops in the Brazilian mountain ranges Mantiqueira and Espinhaço. Revista Brasileira de Botânica 2007;30(4): 569-577.), compared with forest vegetation developing under more structured, deep, and fertile soils (Hopper et al., 2016Hopper SD, Silveira FAO, Fiedler PL. Biodiversity hotspots and Ocbil theory. Plant and Soil 2016; 403: 167-216.).

However, considering the same comparation, total annual fine litterfall and carbon content in inselberg were higher than the respective lowest values (3.5 Mg ha^-1 year^-1and 1.86 Mg ha^-1 year^-1, respectively) estimated for the Atlantic Forest biome in Brazil (Martinelli et al., 2017Martinelli LA, Lins SEM, Santos-Silva JC. Fine litterfall in the Brazilian Atlantic Forest. Biotropica 2017; 49(4): 443-451. ). This result showed the importance of woody vegetation for carbon cycling on inselberg, despite its small vegetation structure characterized by the predominance of herbaceous species (Couto et al., 2017Couto DR, Francisco TM, Manhães VC, Dias HM, Pereira MCA. Floristic composition of a Neotropical inselberg from Espírito Santo state, Brazil: an important area for conservation. Check List 2017; 13(1):1-12.), which reflects the strong environmental filters, such as shallow soil, limited water and nutrient levels, and direct exposure to strong winds (Porembski, 2007Porembski S. (2007) Tropical inselbergs: habitat types, adaptive strategies and diversity patterns. Brazilian Journal of Botany 2007; 30: 579-86.; Couto et al., 2016Couto DR, Dias HM, Pereira MCA, Fraga CN, Pezzopane JEM. Vascular epiphytes on Pseudobombax (Malvaceae) in rocky outcrops (inselbergs) in Brazilian Atlantic Rainforest: basis for conservation of a threatened ecosystem. Rodriguésia 2016; 67(3): 583-601.). Low soil fertility influences the lower structure of the woody plant community and, consequently, both factors are responsible for the lower primary productivity, which is reflected in lower litter production in the ecosystems (Camara et al., 2018aCamara R, Silva VD, Delaqua GCG, Lisbôa CP, Villela DM. Relação entre sucessão secundária, solo e serapilheira em uma Reserva Biológica no estado do Rio de Janeiro, Brasil. Ciência Florestal 2018a; 28(2): 674-686., 2018bCamara R, Pereira MG, Menezes LFT, Segall AB, Castro JSR. Litter dynamics in a forest dune at Restinga da Marambaia, RJ, Brazil. Floresta e Ambiente 2018b; 25(2): e20160046.; Menezes et al., 2020Menezes LFT, Souza RC, Pereira MG, Pires FP, Fanticelle BS, Araujo-Filho PB. Different patterns of nutrient cycling in contiguous phytophysiognomies of Atlantic Forest, Brazil. Floresta e Ambiente 2020; 27(1): e20190045; Câmara et al., 2021Câmara YB, Holanda AC, Costa EJP. Aporte de serapilheira na borda de fragmentos florestais em diferentes estágios sucessionais na Mata Atlântica do Rio Grande do Norte, Brasil. Madera y Bosques 2021; 27(2): e2722179.).

The descending order of macronutrient (N > Ca > K > Mg > P > S) and micronutrient (Mn > Fe > B > Zn > Cu) concentration observed in the inselberg litterfall was the same for a fragment of Seasonal Deciduous Forest in the municipality of Itaara, Rio Grande do Sul state (Schumacher et al., 2018Schumacher MV, Szymczak DA, Trüby P, Londero EK, Marafiga J. Aporte de serapilheira e nutrientes em uma Floresta Estacional Decidual na região central do Rio Grande do Sul. Ciência Florestal 2018; 28(2): 532-541.), and closed to that observed in litterfall from two sites of Alluvial Dense Ombrophilous Forest at different successional stages (Ca > N > K > Mg > P; Mn > Fe > Zn > Cu) in Salto Morato Natural Reserve, Paraná state (Scheer et al., 2011Scheer MB, Gatti G, Wisniewski C. Nutrient fluxes in litterfall of a secondary successional Alluvial Rain Forest in Southern Brazil. Revista de Biología Tropical 2011; 59(4): 1869-1882); the concentration of S and B were not determined in the referred study. Regarding specifically the concentration of micronutrients, the decreasing order was also very similar in comparison with the litterfall of areas of Submontane Dense Ombrophilous Forest (Mn > Fe > Cu > Zn), regardless of the successional stage (initial, intermediate, advanced), in the Guaricica Natural Reserve, Paraná state (Bianchin et al., 2017Bianchin JE, Marques R, Blum H, Oliva EV, Donha CG, Silveira FM et al. Micronutrientes na serapilheira depositada em florestas secundárias no litoral do Paraná. Nativa 2017; 5(6):446-455.).

A similar pattern of micronutrient concentration (Fe > Mn > B > Zn > Cu) was observed in litter standing stock from this studied inselberg; macronutrient concentration, however, differed slightly between litter standing stock from other species (N > Ca > Mg > K > S > P) and litter standing stock from PP (Ca > N > Mg > K > S > P) (Freitas et al., 2015Freitas CAA, Caldeira MVW, Horn SK, Castro KC, Viera M. Serapilheira acumulada em Complexo Rupestre de Granito, Mimoso do Sul, ES. Revista Árvore 2015; 39(4):671-681.). The Principal Component Analysis showed that mainly the concentration of N, S, and Mn, as well as the concentration of P, Ca, B, and Cu are important variables to be considered in future studies of nutrient cycling in inselberg areas, due to its greatest influence on the Principal Component 1.

The higher litterfall, C content, and concentration of N, P, Ca, Mg, S, B, Cu, Fe, Mn, and Zn in litterfall from OS (annual period and at least in two seasons) suggested that these plants probably exhibit a more efficient absorption of nutrient from soil or a greater demand for these nutrients (Scheer et al., 2011Scheer MB, Gatti G, Wisniewski C. Nutrient fluxes in litterfall of a secondary successional Alluvial Rain Forest in Southern Brazil. Revista de Biología Tropical 2011; 59(4): 1869-1882). The litterfall chemical composition, i.e., the nutrient concentration of the litterfall, varies according to the plant species and, therefore, depends on the species composition in the ecosystems (Camara et al., 2018bCamara R, Pereira MG, Menezes LFT, Segall AB, Castro JSR. Litter dynamics in a forest dune at Restinga da Marambaia, RJ, Brazil. Floresta e Ambiente 2018b; 25(2): e20160046.; Schumacher et al., 2018Schumacher MV, Szymczak DA, Trüby P, Londero EK, Marafiga J. Aporte de serapilheira e nutrientes em uma Floresta Estacional Decidual na região central do Rio Grande do Sul. Ciência Florestal 2018; 28(2): 532-541.). It was expected higher accumulation of litter standing stock from PP, since the maintenance of this material is a function of the balance between the amount of litterfall and the rate of decomposition (Camara et al., 2018aCamara R, Silva VD, Delaqua GCG, Lisbôa CP, Villela DM. Relação entre sucessão secundária, solo e serapilheira em uma Reserva Biológica no estado do Rio de Janeiro, Brasil. Ciência Florestal 2018a; 28(2): 674-686.; Carvalho et al., 2019Carvalho FF, Barreto-Garcia PAB, Aragão MA, Virgens AP. Litterfall and litter decomposition in Pinus and native forests. Floresta e Ambiente 2019; 26(3): e20170165.), which tends to be slower for materials with low nutrient concentration (Liao et al., 2022Liao C, Long C, Zhang Q, Cheng X. Stronger effect of litter quality than micro-organisms on leaf and root litter C and N loss at different decomposition stages following a subtropical land use change. Functional Ecology 2022; 36(4): 896-907.).

However, a previous study showed higher accumulation of litter on topsoil from OS, in comparison with the litter standing stock from PP (80.4 % and 19.6 % of the litter layer disposed on the topsoil, respectively) (Freitas et al., 2015Freitas CAA, Caldeira MVW, Horn SK, Castro KC, Viera M. Serapilheira acumulada em Complexo Rupestre de Granito, Mimoso do Sul, ES. Revista Árvore 2015; 39(4):671-681.), which was influenced by the higher litterfall from OS as we detected in the present study. The lack of nutrients and high levels of Al³⁺ in the soil, in addition to lower temperatures, contribute to reducing microbial activity, which results in low rates of decomposition and, therefore, in the accumulation of organic matter on the soil that allows increasing retention of nutrients and water, which provides the establishment and development of vegetation (Benites et al., 2007Benites VM, Schaefer CEGR, Simas FNB, Santos HG. Soils associated with rock outcrops in the Brazilian mountain ranges Mantiqueira and Espinhaço. Revista Brasileira de Botânica 2007;30(4): 569-577.).

On the other hand, the lower nutrient concentration in litterfall from PP suggests that this species presents high nutrient use efficiency, i.e., redistribution of mobile nutrients from older senescent tissues, before their abscission, to younger ones, is increased under conditions of low soil nutrient availability (Scheer et al., 2011Scheer MB, Gatti G, Wisniewski C. Nutrient fluxes in litterfall of a secondary successional Alluvial Rain Forest in Southern Brazil. Revista de Biología Tropical 2011; 59(4): 1869-1882). This fact, except for K concentration that was higher in litterfall from PP, could be essential for vegetation maintenance (Benites et al., 2007Benites VM, Schaefer CEGR, Simas FNB, Santos HG. Soils associated with rock outcrops in the Brazilian mountain ranges Mantiqueira and Espinhaço. Revista Brasileira de Botânica 2007;30(4): 569-577.) and responsible for the high abundance of this lithophyte tree species in the inselberg (Couto et al., 2016Couto DR, Dias HM, Pereira MCA, Fraga CN, Pezzopane JEM. Vascular epiphytes on Pseudobombax (Malvaceae) in rocky outcrops (inselbergs) in Brazilian Atlantic Rainforest: basis for conservation of a threatened ecosystem. Rodriguésia 2016; 67(3): 583-601., 2017Couto DR, Francisco TM, Manhães VC, Dias HM, Pereira MCA. Floristic composition of a Neotropical inselberg from Espírito Santo state, Brazil: an important area for conservation. Check List 2017; 13(1):1-12., 2019Couto DR, Francisco TM, Garbin ML, Dias HM, Pereira MCA, Menini Neto L, Pezzopane JEM. Surface roots as a new ecological zone for occurrence of vascular epiphytes: a case study on Pseudobombax trees on inselbergs. Plant Ecology 2019; 220(11):1071-1084.).

This is a specific physiological plant adaptation which is frequently registered for plants in high-elevation areas, because of the low input of nutrients, such as P and N, via litterfall (Sousa-Neto et al., 2017Sousa-Neto E, Lins S, Martins S, Piccolo M, Ferreira M, Camargo P et al. Litterfall mass and nutrient fluxes over an altitudinal gradient in the coastal Atlantic Forest, Brazil. Journal of Tropical Ecology 2017; 33(4): 261-269.). Thus, the possible high nutrient use efficiency could be one factor that contributes to the adaptation of PP to weakly developed soils, shallow, acidic, and low nutritional quality due to leaching, that is enhanced by high drainage and lesser retention by lacking clays, besides low nutrient content of the parent material, particularly P, which is extremely limiting for plant development and show very low amounts in some soils of inselbergs (Benites et al., 2007Benites VM, Schaefer CEGR, Simas FNB, Santos HG. Soils associated with rock outcrops in the Brazilian mountain ranges Mantiqueira and Espinhaço. Revista Brasileira de Botânica 2007;30(4): 569-577.).

In the comparison between nutrients, K is the most soluble element and, therefore, the most easily released nutrient from decomposing litter (Cavalli et al., 2018Cavalli E, Lange A, Cavalli C, Behling M. Decomposition and release of nutrients from crop residues on soybean-maize cropping systems. Revista Brasileira de Ciências Agrárias 2018; 13(2): e5527.), available for plants in the soil during this process (Lagemann et al., 2022Lagemann MP, Vogel HLM, Vieira FCB, Lorentz LH, Schumacher MV, Dick G. Leaf litterfall, decomposition and nutrients release in a Seasonal Semideciduous Forest in Southern Brazil. Ecologia e Nutrição Florestal 2022; 10: e02.), and has a high rate of retranslocation in the plant organism, which is lower only in comparison with P (Machado et al., 2016Machado MR, Sampaio PTB, Ferraz J, Camara R, Pereira MG. Nutrient retranslocation in forest species in the Brazilian Amazon. Acta Scientiarum Agronomy 2016; 38(1): 93-101.), which is the most limiting nutrient in soil in tropical regions. According to this reasoning, it is believed that the concentration of K in the litterfall from PP would be even higher than what was recorded. Thus, the higher concentration of only one nutrient, K, in the litterfall from PP, in comparison with the litterfall from OS, is a relevant result.

Our pioneer study provided an important contribution about primary production and nutrient cycling in tropical inselberg areas, presenting and suggested that PP can be used in restoration of degraded areas where this species naturally occur, since lower litterfall nutrient concentration may be a consequence of nutrient conservation strategy that minimize the nutritional demand allowing plants to colonize low-fertility soils (Machado et al., 2016Machado MR, Sampaio PTB, Ferraz J, Camara R, Pereira MG. Nutrient retranslocation in forest species in the Brazilian Amazon. Acta Scientiarum Agronomy 2016; 38(1): 93-101.), in addition to the potential of the species in soil fertilization with K. This could be a goal due to some antropic activities that threats the inselberg diversity, which includes ornamental stone mining (Couto et al., 2016Couto DR, Dias HM, Pereira MCA, Fraga CN, Pezzopane JEM. Vascular epiphytes on Pseudobombax (Malvaceae) in rocky outcrops (inselbergs) in Brazilian Atlantic Rainforest: basis for conservation of a threatened ecosystem. Rodriguésia 2016; 67(3): 583-601., 2019Couto DR, Francisco TM, Garbin ML, Dias HM, Pereira MCA, Menini Neto L, Pezzopane JEM. Surface roots as a new ecological zone for occurrence of vascular epiphytes: a case study on Pseudobombax trees on inselbergs. Plant Ecology 2019; 220(11):1071-1084.), presence of invasive species such as Melinis minutiflora P. Beauv. (exotic Poaceae) and Pteridium arachnoideum (Kaulf.) Maxon (native Dennstaedtiaceae), besides coffee and Eucalyptus plantations (Pinto-Junior et al., 2020Pinto-Junior HV, Villa PM, Pereira MCA, Menezes LFT. The pattern of high plant diversity of Neotropical inselbergs: highlighting endemic, threatened and unique species. Acta Botanica Brasilica 2020; 34(4): 645-661.).

5. CONCLUSIONS

Although continuous throughout the year, maximum monthly litterfall in inselberg was verified in the transition between the end of the rainy season and beginning of the dry season, probable as a negative impact of the low precipitation mainly in the previous month and in the respective month. This pattern in commonly observed in Seasonal Semideciduous Forest areas.

Pseudobombax aff. petropolitanum presented lower litterfall (and consequently lower C content) besides lower concentration of N, P, Ca, Mg, S, B, Cu, Fe, Mn, and Zn, which suggested higher nutrient conservation that may could contribute to the high local abundance of this species, although higher K concentration, compared to litterfall from other woody species. Finally, this pattern highlighted the potential of Pseudobombax aff. petropolitanum for restoration of degraded areas by the mining of ornamental rocks in the region of occurrence of this species.

REFERENCES

Alvares CA, Stape JL, Sentelhas PC, Gonçalves JLM, Sparovek G. Köppen’s climate classification map for Brazil. Meteorologische Zeitschrift 2013; 22(6): 711-728.
Araújo VFP, Barbosa MRV, Araújo JP, Vasconcellos A. Spatial-temporal variation in litterfall in seasonally dry tropical forests in Northeastern Brazil. Brazilian Journal of Biology 2020; 80(2): 273-284.
Benites VM, Schaefer CEGR, Simas FNB, Santos HG. Soils associated with rock outcrops in the Brazilian mountain ranges Mantiqueira and Espinhaço. Revista Brasileira de Botânica 2007;30(4): 569-577.
Bianchin JE, Marques R, Blum H, Oliva EV, Donha CG, Silveira FM et al. Micronutrientes na serapilheira depositada em florestas secundárias no litoral do Paraná. Nativa 2017; 5(6):446-455.
Camara R, Silva VD, Delaqua GCG, Lisbôa CP, Villela DM. Relação entre sucessão secundária, solo e serapilheira em uma Reserva Biológica no estado do Rio de Janeiro, Brasil. Ciência Florestal 2018a; 28(2): 674-686.
Camara R, Pereira MG, Menezes LFT, Segall AB, Castro JSR. Litter dynamics in a forest dune at Restinga da Marambaia, RJ, Brazil. Floresta e Ambiente 2018b; 25(2): e20160046.
Câmara YB, Holanda AC, Costa EJP. Aporte de serapilheira na borda de fragmentos florestais em diferentes estágios sucessionais na Mata Atlântica do Rio Grande do Norte, Brasil. Madera y Bosques 2021; 27(2): e2722179.
Carvalho FF, Barreto-Garcia PAB, Aragão MA, Virgens AP. Litterfall and litter decomposition in Pinus and native forests. Floresta e Ambiente 2019; 26(3): e20170165.
Carvalho-Sobrinho JG, Yoshikawa VN. Pseudobombax in Flora e Funga do Brasil. Jardim Botânico do Rio de Janeiro. Disponível em: <Disponível em: https://floradobrasil.jbrj.gov.br/FB603542 >. (Acesso em: 08 set. 2022)
» https://floradobrasil.jbrj.gov.br/FB603542
Cavalli E, Lange A, Cavalli C, Behling M. Decomposition and release of nutrients from crop residues on soybean-maize cropping systems. Revista Brasileira de Ciências Agrárias 2018; 13(2): e5527.
Chave J, Navarrete D, Almeida S, Álvarez E, Aragão LEOC, Bonal D et al. Regional and seasonal patterns of litterfall in tropical South America. Biogeosciences 2010; 7(1): 43-55.
Couto DR, Dias HM, Pereira MCA, Fraga CN, Pezzopane JEM. Vascular epiphytes on Pseudobombax (Malvaceae) in rocky outcrops (inselbergs) in Brazilian Atlantic Rainforest: basis for conservation of a threatened ecosystem. Rodriguésia 2016; 67(3): 583-601.
Couto DR, Francisco TM, Manhães VC, Dias HM, Pereira MCA. Floristic composition of a Neotropical inselberg from Espírito Santo state, Brazil: an important area for conservation. Check List 2017; 13(1):1-12.
Couto DR, Francisco TM, Garbin ML, Dias HM, Pereira MCA, Menini Neto L, Pezzopane JEM. Surface roots as a new ecological zone for occurrence of vascular epiphytes: a case study on Pseudobombax trees on inselbergs. Plant Ecology 2019; 220(11):1071-1084.
Couto DR, Francisco TM, Nascimento MT. Commensalistic epiphyte-phorophyte networks in woody vegetation of tropical inselbergs: Patterns of organization and structure. Austral Ecology 2022, 47: 911-927.
Dick G, Schumacher MV. Litterfall in the Semideciduous Seasonal Forest in southern Brazil. Floresta e Ambiente 2020; 27(2): e20180298.
Francisco TM, Couto DR, Evans DM, Garbin ML, Ruiz-Miranda CR. Structure and robustness of an epiphyte-phorophyte commensalistic network in a neotropical inselberg. Austral Ecology 2018; 43(8):903-914.
Freitas CAA, Caldeira MVW, Horn SK, Castro KC, Viera M. Serapilheira acumulada em Complexo Rupestre de Granito, Mimoso do Sul, ES. Revista Árvore 2015; 39(4):671-681.
Hopper SD, Silveira FAO, Fiedler PL. Biodiversity hotspots and Ocbil theory. Plant and Soil 2016; 403: 167-216.
Lagemann MP, Vogel HLM, Vieira FCB, Lorentz LH, Schumacher MV, Dick G. Leaf litterfall, decomposition and nutrients release in a Seasonal Semideciduous Forest in Southern Brazil. Ecologia e Nutrição Florestal 2022; 10: e02.
Liao C, Long C, Zhang Q, Cheng X. Stronger effect of litter quality than micro-organisms on leaf and root litter C and N loss at different decomposition stages following a subtropical land use change. Functional Ecology 2022; 36(4): 896-907.
Machado MR, Souza RC, Calvi GP, Piña-Rodrigues FCM, Leles PSS. Litterfall: a bio-indicator for edge effect in a Semi-deciduous Seasonal Forest. Floresta e Ambiente 2018; 25(3): e20170528.
Machado MR, Sampaio PTB, Ferraz J, Camara R, Pereira MG. Nutrient retranslocation in forest species in the Brazilian Amazon. Acta Scientiarum Agronomy 2016; 38(1): 93-101.
Martinelli LA, Lins SEM, Santos-Silva JC. Fine litterfall in the Brazilian Atlantic Forest. Biotropica 2017; 49(4): 443-451.
Menezes LFT, Souza RC, Pereira MG, Pires FP, Fanticelle BS, Araujo-Filho PB. Different patterns of nutrient cycling in contiguous phytophysiognomies of Atlantic Forest, Brazil. Floresta e Ambiente 2020; 27(1): e20190045
Miyazawa M, Pavan MA, Muraoka T, Carmo CAFS, Mello WJ. Análises químicas de tecido vegetal. In: Silva FC, editor. Manual de análises químicas de solos, plantas e fertilizantes. Rio de Janeiro: Embrapa Solos; 1999.
Pinto-Junior HV, Villa PM, Pereira MCA, Menezes LFT. The pattern of high plant diversity of Neotropical inselbergs: highlighting endemic, threatened and unique species. Acta Botanica Brasilica 2020; 34(4): 645-661.
Porembski S. (2007) Tropical inselbergs: habitat types, adaptive strategies and diversity patterns. Brazilian Journal of Botany 2007; 30: 579-86.
Scheer MB, Gatti G, Wisniewski C. Nutrient fluxes in litterfall of a secondary successional Alluvial Rain Forest in Southern Brazil. Revista de Biología Tropical 2011; 59(4): 1869-1882
Schumacher MV, Szymczak DA, Trüby P, Londero EK, Marafiga J. Aporte de serapilheira e nutrientes em uma Floresta Estacional Decidual na região central do Rio Grande do Sul. Ciência Florestal 2018; 28(2): 532-541.
Silva FC. Manual de análises químicas de solos, plantas e fertilizantes. 2ª ed. Brasília: Embrapa Informação Tecnológica, 2009.
Sousa-Neto E, Lins S, Martins S, Piccolo M, Ferreira M, Camargo P et al. Litterfall mass and nutrient fluxes over an altitudinal gradient in the coastal Atlantic Forest, Brazil. Journal of Tropical Ecology 2017; 33(4): 261-269.
Tedesco MJ, Gianello C, Bissani CA, Bohnen H, Volkweis SJ. Análise de solo, plantas e outros materiais. 2ª ed. Porto Alegre: Universidade Federal do Rio Grande do Sul; 1995.

Edited by

Associate editor:

Eduardo Vinicius Silva http://orcid.org/0000-0002-1115-0624

Publication Dates

Publication in this collection
30 Sept 2022
Date of issue
2022

History

Received
29 Apr 2022
Accepted
31 Aug 2022

This is an open-access article distributed under the terms of the Creative Commons Attribution License

[1] Alvares CA, Stape JL, Sentelhas PC, Gonçalves JLM, Sparovek G. Köppen’s climate classification map for Brazil. Meteorologische Zeitschrift 2013; 22(6): 711-728.

[2] Araújo VFP, Barbosa MRV, Araújo JP, Vasconcellos A. Spatial-temporal variation in litterfall in seasonally dry tropical forests in Northeastern Brazil. Brazilian Journal of Biology 2020; 80(2): 273-284.

[3] Benites VM, Schaefer CEGR, Simas FNB, Santos HG. Soils associated with rock outcrops in the Brazilian mountain ranges Mantiqueira and Espinhaço. Revista Brasileira de Botânica 2007;30(4): 569-577.

[4] Bianchin JE, Marques R, Blum H, Oliva EV, Donha CG, Silveira FM et al. Micronutrientes na serapilheira depositada em florestas secundárias no litoral do Paraná. Nativa 2017; 5(6):446-455.

[5] Camara R, Silva VD, Delaqua GCG, Lisbôa CP, Villela DM. Relação entre sucessão secundária, solo e serapilheira em uma Reserva Biológica no estado do Rio de Janeiro, Brasil. Ciência Florestal 2018a; 28(2): 674-686.

[6] Camara R, Pereira MG, Menezes LFT, Segall AB, Castro JSR. Litter dynamics in a forest dune at Restinga da Marambaia, RJ, Brazil. Floresta e Ambiente 2018b; 25(2): e20160046.

[7] Câmara YB, Holanda AC, Costa EJP. Aporte de serapilheira na borda de fragmentos florestais em diferentes estágios sucessionais na Mata Atlântica do Rio Grande do Norte, Brasil. Madera y Bosques 2021; 27(2): e2722179.

[8] Carvalho FF, Barreto-Garcia PAB, Aragão MA, Virgens AP. Litterfall and litter decomposition in Pinus and native forests. Floresta e Ambiente 2019; 26(3): e20170165.

[9] Carvalho-Sobrinho JG, Yoshikawa VN. Pseudobombax in Flora e Funga do Brasil. Jardim Botânico do Rio de Janeiro. Disponível em: <Disponível em: https://floradobrasil.jbrj.gov.br/FB603542 >. (Acesso em: 08 set. 2022)
» https://floradobrasil.jbrj.gov.br/FB603542

[10] Cavalli E, Lange A, Cavalli C, Behling M. Decomposition and release of nutrients from crop residues on soybean-maize cropping systems. Revista Brasileira de Ciências Agrárias 2018; 13(2): e5527.

[11] Chave J, Navarrete D, Almeida S, Álvarez E, Aragão LEOC, Bonal D et al. Regional and seasonal patterns of litterfall in tropical South America. Biogeosciences 2010; 7(1): 43-55.

[12] Couto DR, Dias HM, Pereira MCA, Fraga CN, Pezzopane JEM. Vascular epiphytes on Pseudobombax (Malvaceae) in rocky outcrops (inselbergs) in Brazilian Atlantic Rainforest: basis for conservation of a threatened ecosystem. Rodriguésia 2016; 67(3): 583-601.

[13] Couto DR, Francisco TM, Manhães VC, Dias HM, Pereira MCA. Floristic composition of a Neotropical inselberg from Espírito Santo state, Brazil: an important area for conservation. Check List 2017; 13(1):1-12.

[14] Couto DR, Francisco TM, Garbin ML, Dias HM, Pereira MCA, Menini Neto L, Pezzopane JEM. Surface roots as a new ecological zone for occurrence of vascular epiphytes: a case study on Pseudobombax trees on inselbergs. Plant Ecology 2019; 220(11):1071-1084.

[15] Couto DR, Francisco TM, Nascimento MT. Commensalistic epiphyte-phorophyte networks in woody vegetation of tropical inselbergs: Patterns of organization and structure. Austral Ecology 2022, 47: 911-927.

[16] Dick G, Schumacher MV. Litterfall in the Semideciduous Seasonal Forest in southern Brazil. Floresta e Ambiente 2020; 27(2): e20180298.

[17] Francisco TM, Couto DR, Evans DM, Garbin ML, Ruiz-Miranda CR. Structure and robustness of an epiphyte-phorophyte commensalistic network in a neotropical inselberg. Austral Ecology 2018; 43(8):903-914.

[18] Freitas CAA, Caldeira MVW, Horn SK, Castro KC, Viera M. Serapilheira acumulada em Complexo Rupestre de Granito, Mimoso do Sul, ES. Revista Árvore 2015; 39(4):671-681.

[19] Hopper SD, Silveira FAO, Fiedler PL. Biodiversity hotspots and Ocbil theory. Plant and Soil 2016; 403: 167-216.

[20] Lagemann MP, Vogel HLM, Vieira FCB, Lorentz LH, Schumacher MV, Dick G. Leaf litterfall, decomposition and nutrients release in a Seasonal Semideciduous Forest in Southern Brazil. Ecologia e Nutrição Florestal 2022; 10: e02.

[21] Liao C, Long C, Zhang Q, Cheng X. Stronger effect of litter quality than micro-organisms on leaf and root litter C and N loss at different decomposition stages following a subtropical land use change. Functional Ecology 2022; 36(4): 896-907.

[22] Machado MR, Souza RC, Calvi GP, Piña-Rodrigues FCM, Leles PSS. Litterfall: a bio-indicator for edge effect in a Semi-deciduous Seasonal Forest. Floresta e Ambiente 2018; 25(3): e20170528.

[23] Machado MR, Sampaio PTB, Ferraz J, Camara R, Pereira MG. Nutrient retranslocation in forest species in the Brazilian Amazon. Acta Scientiarum Agronomy 2016; 38(1): 93-101.

[24] Martinelli LA, Lins SEM, Santos-Silva JC. Fine litterfall in the Brazilian Atlantic Forest. Biotropica 2017; 49(4): 443-451.

[25] Menezes LFT, Souza RC, Pereira MG, Pires FP, Fanticelle BS, Araujo-Filho PB. Different patterns of nutrient cycling in contiguous phytophysiognomies of Atlantic Forest, Brazil. Floresta e Ambiente 2020; 27(1): e20190045

[26] Miyazawa M, Pavan MA, Muraoka T, Carmo CAFS, Mello WJ. Análises químicas de tecido vegetal. In: Silva FC, editor. Manual de análises químicas de solos, plantas e fertilizantes. Rio de Janeiro: Embrapa Solos; 1999.

[27] Pinto-Junior HV, Villa PM, Pereira MCA, Menezes LFT. The pattern of high plant diversity of Neotropical inselbergs: highlighting endemic, threatened and unique species. Acta Botanica Brasilica 2020; 34(4): 645-661.

[28] Porembski S. (2007) Tropical inselbergs: habitat types, adaptive strategies and diversity patterns. Brazilian Journal of Botany 2007; 30: 579-86.

[29] Scheer MB, Gatti G, Wisniewski C. Nutrient fluxes in litterfall of a secondary successional Alluvial Rain Forest in Southern Brazil. Revista de Biología Tropical 2011; 59(4): 1869-1882

[30] Schumacher MV, Szymczak DA, Trüby P, Londero EK, Marafiga J. Aporte de serapilheira e nutrientes em uma Floresta Estacional Decidual na região central do Rio Grande do Sul. Ciência Florestal 2018; 28(2): 532-541.

[31] Silva FC. Manual de análises químicas de solos, plantas e fertilizantes. 2ª ed. Brasília: Embrapa Informação Tecnológica, 2009.

[32] Sousa-Neto E, Lins S, Martins S, Piccolo M, Ferreira M, Camargo P et al. Litterfall mass and nutrient fluxes over an altitudinal gradient in the coastal Atlantic Forest, Brazil. Journal of Tropical Ecology 2017; 33(4): 261-269.

[33] Tedesco MJ, Gianello C, Bissani CA, Bohnen H, Volkweis SJ. Análise de solo, plantas e outros materiais. 2ª ed. Porto Alegre: Universidade Federal do Rio Grande do Sul; 1995.

Season	PP	OS	TL	PP	OS	TL
	Litterfall			Carbon content
	kg ha^-1
Spring	261.09 B	962.59 A	1,223.68	122.71 B	452.42 A	575.13
Spring	(87.92)	(206.12)	(272.08)	(41.32)	(96.88)	(127.88)
Summer	231.92 B	427.25 A	659.17	109.00 B	200.81 A	309.81
Summer	(112.50)	(96.49)	(119.55)	(52.87)	(45.35)	(56.19)
Autumn	990.96 A	978.35 A	1,969.31	465.75 A	459.82 A	925.57
Autumn	(231.85)	(297.43)	(359.18)	(108.97)	(139.79)	(168.81)
Winter	773.17 A	785.07 A	1,558.24	363.39 A	368.98 A	732.37
Winter	(244.68)	(601.31)	(677.90)	(115.00)	(282.62)	(318.62)
Annual	2,257.15 B	3,153.25 A	5,410.40	1,060.86 B	1,482.03 A	2,542.89
Annual	(322.13)	(683.31)	(729.16)	(151.40)	(321.16)	(342.71)

Litterfall	N	P	K	Ca	Mg	S
Litterfall	(g kg⁻¹)
	Spring
PP	9.64 B	0.73 B	4.99 A	6.51 B	2.27 B	0.89 B
PP	(0.44)	(0.05)	(0.44)	(0.19)	(0.15)	(0.13)
OS	18.28 A	2.30 A	4.48 A	14.55 A	3.52 A	1.59 A
OS	(0.07)	(0.04)	(0.29)	(0.03)	(0.02)	(0.18)
TL	13.96	1.52	4.74	10.53	2.89	1.24
TL	(0.24)	(0.04)	(0.17)	(0.09)	(0.08)	(0.14)
	Summer
PP	9.22 B	0.68 B	4.45 A	12.49 B	3.56 B	0.86 B
PP	(0.27)	(0.02)	(0.04)	(0.21)	(0.03)	(0.05)
OS	17.23 A	2.62 A	3.75 A	15.08 A	3.74 A	1.50 A
OS	(0.47)	(0.08)	(0.18)	(0.70)	(0.15)	(0.11)
TL	13.22	1.65	4.10	13.78	3.65	1.18
TL	(0.16)	(0.03)	(0.07)	(0.35)	(0.07)	(0.04)
	Autumn
PP	7.99 B	0.55 B	2.41 A	12.73 B	3.33 B	0.77 B
PP	(0.27)	(0.02)	(0.03)	(0.07)	(0.05)	(0.02)
OS	18.90 A	1.83 A	1.57 B	18.29 A	3.82 A	1.44 A
OS	(0.12)	(0.13)	(0.18)	(0.95)	(0.24)	(0.13)
TL	13.45	1.19	1.99	15.51	3.57	1.11
TL	(0.18)	(0.06)	(0.10)	(0.46)	(0.10)	(0.06)
	Winter
PP	12.76 B	1.17 A	6.09 A	8.97 B	3.59 A	1.13 A
PP	(0.29)	(0.24)	(0.42)	(0.27)	(0.17)	(0.05)
OS	15.67 A	1.39 A	2.71 B	13.76 A	3.05 A	1.22 A
OS	(0.07)	(0.03)	(0.05)	(0.40)	(0.14)	(0.04)
TL	14.21	1.28	4.40	11.36	3.32	1.17
TL	(0.12)	(0.11)	(0.18)	(0.33)	(0.15)	(0.04)
	Annual
PP	9.90 B	0.78 B	4.49 A	10.17 B	3.19 B	0.91 B
PP	(0.06)	(0.06)	(0.22)	(0.10)	(0.07)	(0.03)
OS	17.52 A	2.03 A	3.13 B	15.42 A	3.53 A	1.44 A
OS	(0.09)	(0.06)	(0.12)	(0.50)	(0.13)	(0.08)
TL	13.71	1.41	3.81	12.80	3.36	1.18
TL	(0.07)	(0.04)	(0.12)	(0.30)	(0.10)	(0.06)

Litterfall	B	Cu	Fe	Mn	Zn
Litterfall	(mg kg⁻¹)
	Spring
PP	28.02 B	7.93 B	139.61 B	246.78 B	37.53 A
PP	(0.78)	(0.30)	(17.14)	(26.37)	(1.62)
OS	70.00 A	11.75 A	183.94 A	487.78 A	50.88 A
OS	(0.65)	(1.35)	(7.20)	(12.51)	(0.99)
TL	49.01	9.85	161.78	367.28	44.21
TL	(0.51)	(0.83)	(11.67)	(14.37)	(1.30)
	Summer
PP	46.00 B	5.34 B	119.17 B	132.33 B	20.81 B
PP	(0.33)	(0.16)	(7.67)	(1.46)	(0.32)
OS	74.60 A	9.28 A	221.83 A	593.06 A	40.64 A
OS	(0.91)	(0.34)	(8.74)	(15.03)	(0.84)
TL	60.79	7.31	170.50	362.69	30.72
TL	(0.41)	(0.11)	(7.94)	(7.47)	(0.33)
	Autumn
PP	44.24 B	5.74 B	124.67 B	151.83 B	17.25 B
PP	(0.53)	(0.54)	(10.36)	(9.40)	(0.56)
OS	91.42 A	11.13 A	207.00 A	551.11 A	34.68 A
OS	(3.56)	(0.58)	(3.17)	(37.38)	(1.14)
TL	67.83	8.44	165.83	351.47	25.96
TL	(1.52)	(0.54)	(3.81)	(14.52)	(0.47)
	Winter
PP	35.86 B	9.83 A	121.83 B	127.11 B	29.83 B
PP	(1.30)	(0.69)	(7.26)	(2.00)	(1.88)
OS	45.79 A	8.22 B	319.83 A	452.78 A	37.40 A
OS	(1.12)	(0.23)	(37.26)	(15.77)	(1.16)
TL	40.82	9.03	220.83	289.94	33.62
TL	(1.00)	(0.45)	(17.40)	(8.73)	(1.45)
	Annual
PP	38.78 B	7.21 B	126.32 B	164.51 B	26.35 B
PP	(0.52)	(0.27)	(6.49)	(7.56)	(0.55)
OS	70.45 A	10.10 A	233.15 A	521.18 A	40.90 A
OS	(0.51)	(0.47)	(9.88)	(11.53)	(0.79)
TL	54.61	8.65	179.74	342.85	33.63
TL	(0.08)	(0.32)	(3.46)	(4.01)	(0.65)

Variable	Eigenvector (PC 1)	Variable	Eigenvector (PC 2)
LTF	0.53	LTF	-0.60
CT_C	0.53	CT_C	-0.60
CC_N	0.97	CC_N	0.19
CC_P	0.90	CC_P	0.33
CC_K	-0.44	CC_K	0.67
CC_Ca	0.81	CC_Ca	-0.45
CC_Mg	0.55	CC_Mg	-0.41
CC_S	0.95	CC_S	0.29
CC_B	0.88	CC_B	-0.20
CC_Cu	0.80	CC_Cu	0.31
CC_Fe	0.63	CC_Fe	0.10
CC_Mn	0.91	CC_Mn	0.21
CC_Zn	0.68	CC_Zn	0.66
Proportion of variance (%)	57.37	Proportion of variance (%)	18.40
Total variance (%)	75.77

Brasil

Brasil

Contribution of Pseudobombax aff. petropolitanum to Nutrient Cycling in Woody Vegetation from a Neotropical Inselberg

Abstract

1. INTRODUCTION AND OBJECTIVES

2. MATERIALS AND METHODS

3. RESULTS

4. DISCUSSION

5. CONCLUSIONS

REFERENCES

Edited by

Associate editor:

Publication Dates

History