Influence of fire history and soil properties on plant species richness and functional diversity in a neotropical savanna

Silva, Danilo Muniz; Batalha, Marco Antônio; Cianciaruso, Marcus V.

doi:10.1590/s0102-33062013000300005

Cited by 23 publications

(14 citation statements)

References 65 publications

(81 reference statements)

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“…Fuel moisture content influences fire behavior (slow or fast spread), propagation, intensity, ignition delay, the degree of flammability and the emissive power of flames. The relationship between ignitability and leaf dry matter will help us to understand the functional role (fuel load) of leaf in fire-prone ecosystems as leaves with low dry matter will have reduced ignitability [3]. Hence, fuel moisture and plant dry matter are considered to be important parameters in any forest fire modeling that attempts to predict fuel ignition.…”

Section: Introductionmentioning

confidence: 99%

Estimating and Up-Scaling Fuel Moisture and Leaf Dry Matter Content of a Temperate Humid Forest Using Multi Resolution Remote Sensing Data

2016

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Vegetation moisture and dry matter content are important indicators in predicting the behavior of fire and it is widely used in fire spread models. In this study, leaf fuel moisture content such as Live Fuel Moisture Content (LFMC), Leaf Relative Water Content (RWC), Dead Fuel Moisture Content (DFMC), and Leaf Dry Matter Content (LDMC) (hereinafter known as moisture content indices (MCI)) were calculated in the field for different forest species at 32 sites in a temperate humid forest (Zaringol forest) located in northeastern Iran. These data and several relevant vegetation-biophysical indices and atmospheric variables calculated using Landsat 7 Enhanced Thematic Mapper Plus (ETM+) data with moderate spatial resolution (30 m) were used to estimate MCI of the Zaringol forest using Artificial Neural Network (ANN) and Multiple Linear Regression (MLR) methods. The prediction of MCI using ANN showed that ETM+ predicted MCI slightly better (Mean Absolute Percentage Error (MAPE) of 6%-12%)) than MLR (MAPE between 8% and 17%). Once satisfactory results in estimating MCI were obtained by using ANN from ETM+ data, these data were then upscaled to estimate MCI using MODIS data for daily monitoring of leaf water and leaf dry matter content at 500 m spatial resolution. For MODIS derived LFMC, LDMC, RWC, and DLMC, the ANN produced a MAPE between 11% and 29% for the indices compared to MLR which produced an MAPE of 14%-33%. In conclusion, we suggest that upscaling is necessary for solving the scale discrepancy problems between the indicators and low spatial resolution MODIS data. The scaling up of MCI could be used for pre-fire alert system and thereby can detect fire prone areas in near real time for fire-fighting operations.

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Section: Introductionmentioning

confidence: 99%

Estimating and Up-Scaling Fuel Moisture and Leaf Dry Matter Content of a Temperate Humid Forest Using Multi Resolution Remote Sensing Data

2016

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“…However, degradation of the environment, such as removal of timber and stock grazing, tends to modify the Cerrado physiognomies, changing them from denser formations to more open ones. Fire also has a fundamental role in the expansion or retraction of different physiognomies (Mistry 1998;Durigan and Ratter 2006;Silva, Batalha, and Cianciaruso 2013). Such attributes have given the Cerrado a high degree of resilience, thus facilitating its recovery from naturally occurring disturbances, even major ones (de Abreu et al 2011).…”

Section: Introductionmentioning

confidence: 99%

Using spectral and textural features from RapidEye images to estimate age and structural parameters of Cerrado vegetation

Gomes¹,

Maillard

2015

International Journal of Remote Sensing

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Cerrado is a savannah biome covering about 60% of the State of Minas Gerais, Brazil, but with a rate of conversion that surpasses that of all other biomes in Brazil. Remote sensing is the only practical means of monitoring the conversion and regeneration of this vegetation formation. The objective of this article is to model the process of regeneration of Cerrado vegetation and to estimate its age using a RapidEye image mosaic and textural features derived from the grey-level co-occurrence matrix. The study area is Parque Estadual Veredas do Peruaçu, a State Park in Minas Gerais, which was a plantation of eucalyptus until 1994 with a broad range of regeneration ages between 15 and 37 years. A total of 47 plots were surveyed for which the exact ages of regeneration are known and other structural variables were measured. Multiple regression and stepwise feature selection were used to create models that explain over 80% of the age, 58% of the crown closure, and 48% of the height of the vegetation. Texture proved essential for capturing the patterns of light and shadow generated by the trees of varying widths and heights.

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“…At the level of the individual plant, N fixation allows plants to satisfy the high N demand and quickly regrow following a disturbance event, which often takes place under low-N conditions (Batterman et al 2013, Vitousek et al 2013, Sheffer et al 2015. Accordingly, repeated disturbances by fire in savanna are thought to have selected for an abundance of N-fixing relative to non-fixing species and individuals in the savanna biome (Högberg 1986a, b, da Silva and Batalha 2008, Cramer et al 2010, Silva et al 2013a.…”

mentioning

confidence: 99%

Aridity, not fire, favors nitrogen‐fixing plants across tropical savanna and forest biomes

Pellegrini

Staver

Hedin

et al. 2016

Ecology

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Abstract. Tropical savannas are hypothesized to be hot spots of nitrogen-fixer diversity and activity because of the high disturbance and low nitrogen characteristic of savanna landscapes. Here we compare the abundances of nitrogen-fixing and non-fixing trees in both tropical savannas and tropical forests under climatically equivalent conditions, using plant inventory studies across 566 plots in South America and Africa. A single factor, aridity, explained 19-54% of the variance in fixer abundance, and unexpectedly was more important than fire frequency, biome, and continent. Nitrogen fixers were more abundant in arid environments; as a result, African savannas, which tend to be drier, were richer in nitrogen fixers than South American savannas. Fixer abundance converged on similar levels in forests in both continents. We conclude that climate plays a greater role than fire in determining the distribution of nitrogen fixers across tropical savanna and forest biomes.

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Influence of fire history and soil properties on plant species richness and functional diversity in a neotropical savanna

Cited by 23 publications

References 65 publications

Estimating and Up-Scaling Fuel Moisture and Leaf Dry Matter Content of a Temperate Humid Forest Using Multi Resolution Remote Sensing Data

Estimating and Up-Scaling Fuel Moisture and Leaf Dry Matter Content of a Temperate Humid Forest Using Multi Resolution Remote Sensing Data

Using spectral and textural features from RapidEye images to estimate age and structural parameters of Cerrado vegetation

Aridity, not fire, favors nitrogen‐fixing plants across tropical savanna and forest biomes

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