Evaluation of Forest Fire Danger Indexes for Eucalypt Plantations in Bahia, Brazil

White, Larissa Alves Secundo; White, Benjamin Leonardo Alves; Ribeiro, Genésio Tâmara

doi:https://doi.org/10.1155/2015/613736

International Journal of Forestry Research

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Research Article | Open Access

Volume 2015 | Article ID 613736 | https://doi.org/10.1155/2015/613736

Evaluation of Forest Fire Danger Indexes for Eucalypt Plantations in Bahia, Brazil

Larissa Alves Secundo White,¹Benjamin Leonardo Alves White,²and Genésio Tâmara Ribeiro¹

Academic Editor: Piermaria Corona

Received14 Apr 2015

Revised18 Jun 2015

Accepted18 Jun 2015

Published02 Jul 2015

Abstract

A Forest Fire Danger Index is a valuable tool in forest fire prevention and firefight because it grades fire occurrence possibility on a daily basis. Six Fire Danger Indexes were tested for accuracy based on forest fire occurrence in eucalyptus plantations of the north coast of Bahia, Brazil. They are Angstron, Nesterov, Telicyn Logarithmic Index, Monte Alegre, Rodríguez and Moretti, and Modified Monte Alegre. The results were analyzed using two parameters of the Heidke Skill Score test: Skill Score index and Percentage of Success. The Telicyn Logarithmic Index proved to be the most accurate for the study area.

1. Introduction

Every year, forest fires are responsible for economic impact and local biodiversity loss in almost every country in the world [1]. In Brazil from 1998 to 2002, 85 thousand hectares burned, including 13.5 thousand hectares of eucalyptus [2]. Also in Brazil, between the periods of 1983–1987, 1994–1997, forest fires destroyed areas of 134 thousand and 265 thousand hectares, respectively. And in 1963, in the Brazilian state of Paraná, one of the worst fires occurred, devastated 2 million hectares and killed 110 people [3, 4].

Fires break dynamic equilibrium in a forest and cause increasing susceptibility to erosion, mudslides, and pests (particularly ants and termites). They damage infrastructure, melting electrical and communication wires, block roads with burning debris, and pollute the atmosphere with CO₂. Wildlife, livestock, pets, and humans in the area suffer respiratory complications, burns, and death [5–12].

Therefore, the need for more effective fire prevention is obviously urgent, particularly in regions more susceptible, due to the type of vegetation, climatic conditions [13, 14], and the amount of human disturbance [15], and even more so in those regions that represent conservation or economic interest [16].

With this goal in mind, in the middle of the 20th century, Angstron and Nesterov developed Fire Danger Indexes that predict an area’s fire susceptibility based on weather conditions. The success of these tools has inspired many others to try to develop more accurate indexes for their own regions. The indexes are so important because they help determine the best time to intensify preventive measures, such as employing more park rangers; raising public awareness; organizing and training volunteers; increasing forest surveillance; constructing firebreaks; and choosing the best days to safely reduce the fuel loads with controlled burnings [17, 18].

Unfortunately, in Brazil, there are a few national preventive educational campaigns against forest fire. Also, there is no Forest Fire Danger Index that is especially calibrated for the entire country, as can be found in other countries such as Portugal, Spain, Australia, Canada, and the USA [19–23]. Regionally though, the Monte Alegre Index (FMA) and the Modified Monte Alegre Index (FMA+) were developed especially for the south and southwest regions of the country and presented good results [24, 25]. However, few studies have been directed to the northeast region (e.g., [13, 26–28]), where this study is based.

So, aiming at helping diminish losses caused by fire in eucalyptus plantations at the study site, this work evaluated the forecast efficiency of the six most used Fire Danger Indexes in Brazil: Telicyn Logarithmic; Angstron; Nesterov; Rodríguez and Moretti; FMA; and FMA+ [26, 27, 29–32]. Although there exist other Fire Danger Indexes commonly used in other countries, such as the Canadian Fire Weather Index (FWI) [20, 21] and the National Fire Danger Rating System (NFDRS) [19], both were not tested due to unavailability of climate data for the study area to assess them.

2. Material and Methods

2.1. The Study Area

The study area is located on the north coast of Bahia between latitudes 11°31′S and 11°58′S and longitudes 38°11′W and 38°38′W. The plantations belong to the Bahia Specialty Cellulose company, which has approximately 100,000 ha planted with hybrid eucalyptus resulting from the cross Eucalyptus grandis (Hill ex. Maiden) × Eucalyptus urophylla (S. T. Blake) for cellulose production (Figure 1).

The meteorological station used in this work is placed at an altitude of 233 m, latitude 11°50′42′′S, and longitude 38°22′02′′W, in the municipality of Inhambupe, Bahia. The climate of the town is semiarid with an average annual temperature of 24°C, total rainfall of around 900 mm per year, and the rainy season from April to July [33]. The Atlantic Forest and Caatinga biomes are present in the region, and besides the plantation of eucalyptus, there are other minor forms of agricultural and some livestock is raised [34–36].

2.2. Data Processing

The relationship between the Forest Fire Danger Indexes and forest fire occurrence, obtained from the Bahia Specialty Cellulose company, was analyzed using daily meteorological data for 1 January 2002 to 31 December 2012, comprising a total of 4018 days (11 years) and forest fire occurrence data of the same period. Fire occurrence data were categorized in binary form, where the value “1” represents days with fire and “0” represents days without fire. Analysis of variance statistical analysis (ANOVA) was used to verify significant difference between the fire occurrence among the months and years.

The variables, air temperature at 1 pm and 3 pm, relative humidity at 1 pm and 3 pm, deficit saturation of the air, dew temperature, daily average wind speed, daily rainfall, and the number of consecutive days without rain, were quantified and applied in the following Forest Fire Danger Indexes: Angstron [37], Nesterov [38], Telicyn Logarithmic [39], FMA [24], Rodríguez and Moretti [40], and FMA+ [25].

To evaluate these six Fire Danger Indexes, the Heidke Skill Score (HSS) was used [41] (Table 1). The HSS measures the fractional improvement of the forecast over the standard forecast. The parameters from HSS that were chosen were the Skill Score (SS) and the Percentage of Success (PS), according to Sampaio [30], Nunes [25], and White [26] (1). The HSS methodology has been utilized and trusted by many authors (e.g., [3, 25, 26, 30, 31, 36, 42, 43]):

3. Results

3.1. Fire Occurrence Distribution

Of the 4018 days analyzed, 351 days (8.74%) had forest fire occurrence in the study area. The year of 2010 had the most fires, 49, while 2008 had the least, 14. However, according to ANOVA test, the difference between those years was not significant (; ). But when verifying months instead of the years, there was observed a significant difference among them (, ).

It was possible to separate the months in two distinct groups according to the forest fire occurrence: the group with higher fire occurrence, October, November, December, January, February, and March (; ), and the group with low fire occurrence, April, May, June, July, August, and September (; ) (Table 2).

3.2. Fire Danger Indexes Analysis

Applying the HSS to gauge the Fire Danger Indexes, it was determined that Telicyn Logarithmic Index is the best model to forecast fire occurrence in the study area, followed by the Angstron, FMA+, Nesterov, FMA, and Rodríguez and Moretti, respectively (Table 3).

According to the Telicyn Logarithmic daily-risk forecast, October, November, December, January, February, and March form the semester that presents the highest risk of fire occurrence, which is in accordance with the daily fire occurrence observation (Figure 2).

4. Discussion

Due to the size and diversity of climes in Brazil, several studies obtained different results when applying the Forest Fire Danger Indexes across the country; for example, Soares [29], Zaicovski et al. [44], and Deppe et al. [45] describe the FMA as the most appropriate model to forecast fire occurrence for the South region of Brazil, whose months of May, June, July, and August are those with most forest fire occurrence.

Borges et al. [31] determined that the FMA+ was the best index for the state of Espírito Santo, in Southeastern Brazil. Other studies in the Southeastern region, in the state of Minas Gerais, indicate the months June to October to be with most forest fire occurrence [42, 46] and May to September in Rio de Janeiro [47].

Narciso et al. [32] determined that the Nesterov Index is the most adequate for Mato Grosso do Sul, in the Midwest of Brazil, which presents June, July, August, and September as the months with most forest fire occurrence [48].

According to White and Ribeiro [27], the Angstron model functions best for Sergipe, in the Brazilian Northeast region, with December to February as the months with most forest fire occurrence. For the same geographic region (Northeast), but around 700 km up to North, Santana et al. [49] determined, for the state of Rio Grande do Norte, that the months August, September, October, and November present more forest fire occurrence.

These observations emphasize the climatic differences throughout Brazil and confirm what Bugalho and Pessanha [50] and Borges et al. [31] concluded: depending on the patterns of climatic variables in a study area, one Forest Fire Danger Index may predict better than another.

Besides assessing current available Fire Danger Index, new models can be created. White et al. [51], for example, developed a new index, the White model, due to the low accuracy of the existing models for the study area.

By determining or creating the best Forest Fire Danger Index for each region, better capitalization on the financial investments can be made in forest protection.

5. Conclusion

Based on the results from this study, the Telicyn Logarithmic Index performed better for predicting daily forest fire occurrence in the study area. Also, it is possible to affirm with statistical significance that October to March are the months with higher forest fire occurrence.

Even though this study defined the best Forest Fire Danger Index for the study area, all the indexes tested presented poor result with a Skill Score ≤0.1. This outcome supports the need for new studies using other indexes, such as the FWI or the NFDRS, or a development of a new Forest Fire Danger Index for the study area.

Conflict of Interests

The authors declare that there is no conflict of interests regarding the publication of this paper.

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Copyright

Copyright © 2015 Larissa Alves Secundo White et al. This is an open access article distributed under the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

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