In degraded tropical pastures, active restoration strategies have the potential to facilitate forest regrowth at rates that are faster than natural recovery, enhancing litterfall, and nutrient inputs to the forest floor. We evaluated litterfall and nutrient dynamics under four treatments: plantation (entire area planted), tree islands (planting in six patches of three sizes), control (same age natural regeneration), and young secondary forest (7-9-yr-old natural regeneration). Treatments were established in plots of 50 Â 50 m at six replicate sites in southern Costa Rica and the annual litterfall production was measured 5 yr after treatment establishment. Planted species included two native timber-producing hardwoods (Terminalia amazonia and Vochysia guatemalensis) interplanted with two N-fixing species (Inga edulis and Erythrina poeppigiana). Litter production was highest in secondary forests (7.3 Mg/ha/yr) and plantations (6.3), intermediate in islands (3.5), and lowest in controls (1.4). Secondary forests had higher input of all nutrients except N when compared with the plantation plots. Inga contributed 70 percent of leaffall in the plantations, demonstrating the influence that one species can have on litter quantity and quality. Although tree islands had lower litterfall rates, they were similar to plantations in inputs of Mg, K, P, Zn, and Mn. Tree islands increased litter production and nutrient inputs more quickly than natural regeneration. In addition to being less resource intensive than conventional plantations, this planting design promotes a more rapid increase in litter diversity and more spatial heterogeneity, which can accelerate the rate of nutrient cycling and facilitate forest recovery.Abstract in Spanish is available at http://www.blackwell-synergy.com/loi/btp.
Brazil's riparian forests are continuously threatened by conversion into agricultural areas, causing not only degradation and loss of vegetation but also negative changes in soil properties and ecosystem services. In order to select vegetation and soil variables that are affected by degradation and to evaluate whether forest structure can be used as a proxy for soil ecosystem services, two watersheds in eastern Amazon were chosen as a study area in which four degradation levels were identified (very high, high, moderate and low), based on forest canopy openness and height. Vegetation structural characteristics, water infiltration rates, and soil properties were evaluated in 24, 1,000 m 2 permanent plots. Results indicated that forest degradation significantly reduced soil carbon, phosphorus, cation exchange capacity, silt proportion, total porosity, and water content as well as water infiltration rate. Vegetation structure was a good proxy for monitoring soil ecosystem services (i.e. regulation of water flow, erosion control and life-supporting). Tree height and basal area, as well as herb biomass, were identified as the best vegetation indicators for changes in soil properties that underlie ecosystem services. Application of this strategy may facilitate the monitoring and modeling of riparian forest ecosystem services across broader spatial scales, to help guide efficient restoration efforts and conservation policies.
BackgroundRiparian forests provide ecosystem services that are essential for human well-being. The Pepital River is the main water supply for Alcântara (Brazil) and its forests are disappearing. This is affecting water volume and distribution in the region. Promoting forest restoration is imperative. In deprived regions, restoration success depends on the integration of ecology, livelihoods and traditional knowledge (TEK). In this study, an interdisciplinary research framework is proposed to design riparian forest restoration strategies based on ecological data, TEK and social needs.MethodsThis study takes place in a region presenting a complex history of human relocation and land tenure. Local populations from seven villages were surveyed to document livelihood (including ‘free-listing’ of agricultural crops and homegarden tree species). Additionally, their perceptions toward environmental changes were explored through semi-structured interviews (n = 79). Ethnobotanical information on forest species and their uses were assessed by local-specialists (n = 19). Remnants of conserved forests were surveyed to access ecological information on tree species (three plots of 1,000 m2). Results included descriptive statistics, frequency and Smith’s index of salience of the free-list results.ResultsThe local population depends primarily on slash-and-burn subsistence agriculture to meet their needs. Interviewees showed a strong empirical knowledge about the environmental problems of the river, and of their causes, consequences and potential solutions. Twenty-four tree species (dbh > 10 cm) were found at the reference sites. Tree density averaged 510 individuals per hectare (stdv = 91.6); and 12 species were considered the most abundant (density > 10ind/ha). There was a strong consensus among plant-specialists about the most important trees. The species lists from reference sites and plant-specialists presented an important convergence.ConclusionsSlash-and-burn agriculture is the main source of livelihood but also the main driver of forest degradation. Effective restoration approaches must transform problems into solutions by empowering local people. Successional agroforestry combining annual crops and trees may be a suitable transitional phase for restoration. The model must be designed collectively and include species of ecological, cultural, and socioeconomic value. In deprived communities of the Amazon, forest restoration must be a process that combines environmental and social gains.
* Autor correspondente: guilirous@yahoo.ca RESUMOAs florestas ripárias provêem serviços ecossistêmicos essenciais à humanidade, mas estão sendo degradadas em um ritmo acelerado na Amazônia. Esse estudo teve como objetivo quantificar os estoques de carbono acima e abaixo do solo de florestas ripárias com quatro níveis de degradação (muito alta, alta, média e baixa) em duas microbacias (Rio Pepital e Rio Grande) em Alcântara (Maranhão), na Amazônia Oriental. Foram instaladas 24 parcelas permanentes de 1.000 m 2 , onde a vegetação (árvores, arbustos, herbáceas, lianas e palmeiras), a necromasa (serapilheira, árvores mortas, galhos) e o solo (0-20 cm e raízes) foram amostrados. A biomassa foi estimada mediante modelos alométricos (vegetação com DAP > 1 cm e árvores mortas) e de forma destrutiva (herbáceas, serapilheira, galhos finos, raízes). O estoque total de carbono nas florestas ripárias mais conservadas variou entre 88 e 202 Mg(C) ha -1. A degradação reduziu significativamente o estoque de carbono em todos os compartimentos (até 97% na biomassa viva acima do solo, até 91% de necromassa e até 47% no solo). Nas áreas conservadas, a biomassa viva acima do solo tem a maior participação no estoque total de carbono (> 70%), principalmente devido às árvores de grande porte. O estoque de carbono nos diferentes compartimentos estão fortemente relacionados entre si e também com a abertura do dossel. A incorporação desses resultados em modelos regionais de carbono pode auxiliar na implementação e revisão do Código Florestal Brasileiro, em particular na restauração das florestas ripárias onde a agricultura está consolidada. PALAVRAS-CHAVE: Maranhão, mata ciliar, conservação florestal, serviços ecossistêmicos, sucessão ecológica. Impact of degradation on carbon stock of riparian forests in the eastern Amazon, Brazil ABSTRACTRiparian forests provide essential ecosystem services to humanity, but are being degraded at an accelerated rate in the Amazon. This study aimed to quantify carbon stocks above and below ground in riparian forests with four levels of degradation (very high, high, medium and low) in two watersheds (Pepital Rio and Rio Grande) in Alcântara, Eastern Amazon. Twenty-four permanent plots of 1,000 m 2 were installed, and vegetation (trees, shrubs, herbs, lianas and palms), necromass (litter, dead trees, branches) and soil (0-20 cm and roots) were sampled. The biomass was estimated using allometric models (vegetation with dbh> 1 cm and dead trees) and destructively (herbaceous, litterfall, branches, roots). The total carbon stock in the most conserved riparian forests ranged between 88 and 202 Mg(C) ha -1. Degradation significantly reduced carbon stock in all compartments (up to 97% in above-ground biomass, up to 91% of necromass, and up to 47% in soils). In conserved areas, the aboveground biomass is the largest compartment of the total carbon stock (> 70%), mainly due to large trees. The carbon stock in the different compartments are strongly correlated with each other and with the canopy opening. The incorpor...
Multi‐year studies comparing changes in litterfall biomass and nutrient inputs in sites under different restoration practices are lacking. We evaluated litterfall dynamics and nutrient inputs at 5 yr and after a decade of recovery in four treatments (natural regeneration—no planting, plantation—entire area planted, tree islands—planting in patches, and reference forest) at multiple sites in an agricultural landscape in southern Costa Rica. We inter‐planted two native species (Terminalia amazonia and Vochysia guatemalensis) and two naturalized N‐fixing species (Inga edulis and Erythrina poeppigiana) in plantation and island treatments. Although litterfall N was higher in plantations in the first sampling period, litter production and overall inputs of C, N, Ca, Mg, P, Cu, Mn, and Fe did not differ between island, plantation, or reference forest after a decade; however, all were greater than in natural regeneration. Potassium inputs were lower in the natural regeneration, intermediate in island and plantation, and greater in reference forest. The percentage of litterfall comprised by the N‐fixing planted species declined by nearly two‐thirds in both plantations and islands between sampling periods, while the percentage of V. guatemalensis more than doubled, and the percentage from naturally regenerated species increased from 27 to 47 percent in islands. Island and plantation treatments were equally effective at restoring litterfall and nutrient inputs to levels similar to the reference system. The nutrient input changed substantially over the 7‐yr interval between measurements, reflecting shifts in vegetation composition and demonstrating how rapidly nutrient cycling dynamics can change in recovering forests.
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