Nativa, Sinop, v. 11, n. 2, p. 148-160, 2023.
Pesquisas Agrárias e Ambientais
DOI: https://doi.org/10.31413/nativa.v11i2.15355
ISSN: 2318-7670
Litterfall and herbaceous plants regeneration in planted forests at post
prescribed fire in the Cerrado-Amazon transition
Ana Paula Slovinski de Oliveira CAMARGO1, Daiane Cristina de LIMA1,
Josiane Fernandes KEFFER1, Rafael ARRUDA1, Adilson Pacheco de SOUZA1*
1 Posgraduate Program in Environmental Sciences, Federal University of Mato Grosso, Sinop, MT, Brazil.
*E-mail: adilson.souza@ufmt.br
Submission: 04/20/2023; Accepted on 05/22/2023; Published on 06/12/2023.
ABSTRACT: Information on the effects of prescribed burning in forest areas is essential for numerous
environmental and forest production applications, including preventive maintenance against forest fires. In this
article, we evaluated the effects generated at different interfaces (borders) of a homogeneous area of eucalyptus,
after the occurrence of prescribed burns. The litter recovery and the regeneration of herbaceous material were
evaluated, which may compose the combustible material for the occurrence of new fires. The forest inventory
include measurements of circumference at breast height (CBH), commercial and total height, canopy density
percentage, and number alive and dead trees. The percentage of herbaceous plants and litterfall differentiation
were determined through photos taken in the field and subjected to pixel analysis in the Adobe Photoshop Cs6
program. The litterfall was classified into leaves, barks, and branches, and the herbaceous plants was subjected
to identification and quantification of phytosociological variables. The prescribed fire did not affect the survival
and development of trees, since the values were consistent with the community age. Leaves represented the
highest litterfall fraction (47.69%) and thick branches the lowest (1.79%), both in the eucalyptus/agriculture
interface. The herbaceous plants totalized 120 individuals, with predominance of grass species and had higher
abundance in the eucalyptus/agriculture and eucalyptus/forest interfaces.
Keywords: planted forests; prescribed fire; post-fire; combustible matter; regeneration; forestry.
Serrapilheira e regeneração herbácea em floresta plantada pós queimas prescritas
na transição Cerrado-Amazônia
RESUMO: Informações sobre os efeitos da queima prescrita em áreas florestais são essenciais para inúmeras
aplicações ambientais e para a produção florestal, incluindo a manutenção preventiva contra incêndios
florestais. Neste artigo, avaliamos os efeitos gerados em diferentes interfaces (bordas) de uma área homogênea
de eucalipto, após a ocorrência de queimadas prescritas. Foi avaliada a recomposição da serapilheira e a
regeneração do material herbáceo, que serão os componentes do material combustível para a ocorrência de
novos incêndios. O inventário da floresta plantada incluiu medidas de circunferência à altura do peito (CBH),
altura comercial e total, percentual de densidade de copa e número de árvores vivas e mortas. A porcentagem
de plantas herbáceas e a diferenciação da serapilheira foram determinadas por meio de fotos tiradas no campo
e submetidas à análise de pixels no programa Adobe Photoshop Cs6. A serapilheira foi classificada em folhas,
cascas e galhos, e as plantas herbáceas foram submetidas à identificação e quantificação de variáveis
fitossociológicas. O fogo prescrito não afetou a sobrevivência e o desenvolvimento das árvores, pois os valores
foram condizentes com a idade da comunidade. As folhas representaram a maior fração de serapilheira
(47,69%) e galhos grossos a menor (1,79%), ambas na interface eucalipto/agricultura. As plantas herbáceas
totalizaram 120 indivíduos, com predominância de espécies gramíneas e tiveram maior abundância nas
interfaces eucalipto/lavoura e eucalipto/floresta.
Palavras-chave: florestas plantadas; fogo prescrito; pós-fogo; matéria combustível; regeneração; silvicultura.
1. INTRODUCTION
The forest sector in Brazil has a large representativeness
in the international market of forest products, occupying the
first and second place in cellulose exports and production,
respectively, after only the United States (IBGE, 2021). Brazil
has approximately 9.93 million hectares (ha) of planted
forests ((trees planted, harvested and replanted in previously
degraded areas), with 7.53 million hectares of eucalyptus
plantations (IBÁ, 2022), with increasing expansion in all
states of Brazil.
In the state of Mato Grosso, the planted area with
eucalyptus in 2021 was 188.605 ha, with a mean increase of
28% from 2009, and an estimation of 700,000 hectares for
2028 (IBÁ, 2022). Currently, the hybrid Eucalyptus urograndis
(Eucalyptus urophylla × Eucalyptus grandis H-13) have been
planted in Mato Grosso for energy purposes focused on
meeting the wood demand due to the implementation of
several maize ethanol production industries in the region, and
demands for drying of agricultural products and
slaughterhouses (ZIERO et al., 2021).
Camargo et al.
Nativa, Sinop, v. 11, n. 2, p. 148-160, 2023.
149
However, homogeneous forests present high risk of fire
due to the continuous accumulation leaves and branches in
the ground from plants and ground vegetation that have low
decomposition rates, which serve as combustible matter for
fires (BORGES et al., 2012). This is worrisome, mainly in
Mato Grosso, since the state presents a dry period that favors
even more the incidence of fires (CASAVECCHIA et al.,
2019).
The litterfall deposition and accumulation dynamics is
highly variable, since the quantity of matter is affected by
climate dynamics and other factors, such as the ecosystem
category, plant age, planting spacing, and plant-environment
interaction (CIZUNGU et al., 2014; ALONSO et al., 2015).
The quantification of litterfall assists in the forest protection
management for fast-growth species, such as eucalyptus,
since the biomass management can be preventively done
depending on the class of combustible matter, using efficient
prevention techniques and control of fires (BORGES et al.,
2012; ALVES et al., 2017).
Several alternatives can be adopted to mitigate or prevent
the occurrence of forest fires, which are chosen depending
on many factors, such as financial and technological
resources and state policies (BATISTA, 2009; RAMALHO
et al., 2021). The partial or total removal of combustible
matter through prescribed fire is among these options; it
presents positive results in biomass control and mitigation of
negative effects of fires (MCCAW, 2013; ALVES et al.,
2017).
Prescribed or controlled fire has been widely used as a
management tool in production systems with planted forests,
maintaining the habitat quality and stimulating regeneration
in the managed areas (BOWMAN et al., 2009;
VOGELMANN et al., 2015). According some studies, this is
a practical and efficient method for decreasing combustible
matter and prevent fires in eucalyptus forests that do not
affect tree development and assists in decreasing weed
competition, insects, fungi, and litterfall, when rationally
applied (BERENHAUSER, 1972; MCCAW, 2013;
GUIMARÃES et al., 2014; LIMA et al., 2020a).
Controlled fire in Brazil was legalized by Brazilina Forest
Code (law 12.651/2012) and the Federal Decree no. 2.661,
of 8 of July 1998, whose Article 2 considers the use of fire
for the production and management in agroforestry or forest
activities, and for scientific and technological researches in
areas with previously defined limits (BRASIL, 1998).
However, the inconsequent use of fire can reach catastrophic
proportions, by decreasing biodiversity, releasing high levels
of greenhouse gases, hindering local and regional air quality,
facilitating the entry and proliferation of invasive species, and
modifying the structure and standards of production
processes (SHLISKY et al., 2007; GUIMARÃES et al., 2014).
Therefore, information on the dynamics of Eucalyptus sp.
regarding the production of combustible matter (litterfall and
herbaceous plants) in the sub-forest, and on fire
characteristics and periods more prone for prescribed fire is
important (ALVES et al., 2017; LIMA et al., 2020a,b). Thus,
the objective of this work was to survey, evaluate, and
estimate the availability of combustible matter formed by the
litterfall and regeneration of herbaceous plants in the sub-
forest of a planted forest of eucalyptus in the Cerrado-
Amazon transition region of the state of Mato Grosso, Brazil,
in different environmental interfaces and post-controlled fire
periods.
2. MATERIALS AND METHODS
2.1. Area of study
The study was developed in the Santo Antônio Farm,
which belongs to the BRF Company (Brazil Food SA), in the
municipality of Sorriso, Mato Grosso, Brazil (12°51'44''S,
55°52'34''W, and altitude of 365 m). The predominant
climate in Sorriso is AW, hot and wet, according to the
Köppen classification, with two well-defined seasons: rainy
(October to April) and dry (May to September) (SOUZA et
al., 2013).
The experimental area was covered with forest
plantations of the species E. urograndis (hybrid clone of E.
urophylla and E. grandis - H13) with 6.5 years of age in April
2018, with spacing of 3 × 3 meters. The plantations were in
different environmental interfaces, with a border interface
with agriculture (soybean/maize/cotton) at West and an
interface with native riparian forest with plant formations
typical of arborized savannas and submountain semi-decidual
seasonal forest at East (Delmon et al., 2013), termed in this
study as eucalyptus/agriculture (EA), eucalyptus/eucalyptus
(EE) and eucalyptus/ remnant of native forest (EF)
interfaces (Figure 1). The eucalyptus plantation area in the EF
interface were partially flooded due to proximity of a lake and
the rainfall regime between October to April.
Figure 1. Experimental area with Eucalyptus urograndis plantation and delimitation of sampled plots in Sorriso, MT, Brazil.
Figura 1. Área experimental de Eucalyptus urograndis e delimitação das parcelas amostrais em Sorriso, MT, Brasil.
Litterfall and herbaceous plants regeneration in planted forests at post prescribed fire
Nativa, Sinop, v. 11, n. 2, p. 148-160, 2023.
150
Three prescribed fires were carried out in May 2015,
September 2015, and August 2016 in the EA, EE, and EF
interfaces of the experimental area (distant 30.0 m from the
borders), thus, they were evaluated at 36, 32, and 21 months
after the controlled fire, respectively, since the collections of
litterfall and herbaceous plants took place in April 2018. The
plots with prescribed fire were 3.0 m wide and 20.0 m long;
they were designed following the planting line and were at
the same level, with 1.0-m firebreaks in all interfaces. Three
replications were used for each interface and post-fire
periods. The control plots (reference areas) were considered
in the same environmental interfaces, however they did not
receive controlled burning and the plants were 77 months
old.
2.2. Plantation inventory
The plantation homogeneity was evaluated in the
different interfaces considering the following variables of
trees in the plots: circumference at breast height (CBH), using
a diametric tape; comercial (CH) and total height (TH), using
a clinometer; canopy density percentage, using a leveled
convex spherical densiometer in the combustible matter
collection points; and number alive and dead trees.
2.3. Combustible matter collection
Combustible matter, litterfall, and herbaceous plants in
the ground surface were collected in April 2018, in the three
environmental interfaces (Figure 2), following the
recommendations of Alves et al. (2017). Sampling points at
5, 10, and 15 m were selected in each plot; they were marked
and identified after the fire. A polyvinyl chloride frame with
area of 1.0 m² (Figure 2) was used to delimitate the sampling
points, and thin and thick branches were sectioned in the
limits of the sampling frame; then, all litterfall was collected
and stored in black plastic bags, labeled, and sent for
screening. The classification followed the methodology used
by Rothermel (1972) and Alves et al. (2017), considering the
following classes: leaves, barks, and branches. Branches were
classified according to their diameters (cm) as thin (≤0.7),
medium (≥0.7 and ≤2.50), or thick (≥2.50) and then placed
in paper bags (Figure 3).
The herbaceous plants within the frame area were
previously classified as weeds, lianas, shrubs, and forest
species, and the plants were quantified, measured for
maximum height up to 1.80 m, and identified according to
Lorenzi (2008). Then, the plants were uprooted with the
whole root system, weighed in the field to obtain the fresh
weight, and stored in labeled paper bags.
The samples of areas without fire (controls) were
collected parallelly at 10.0 m distant from each plot, in
interrows. In this case, five treatments were established:
control, native forest, and different post-fire periods: May
2015 (36 months), September 2015 (32 months), August
2016 (21 months).
The percentage of herbaceous plants and litterfall
differentiation in post-fire areas were determined through
photos taken from the sampling frame areas using an above
ground camera at 1.30 m height, with three replications/plots
for areas with prescribed fire and one replication for controls.
The images were evaluated in the Adobe Photoshop Cs6
program to determine the percentage, by counting the pixels
of the images (Figure 4).
The combustible matter collected was placed in forced
air-circulation oven, with temperature of 65±2 °C for 72
hours and then weighed in an analytical balance with
precision of 0.0001 g to assess its dry weight.
Figure 2. Environmental interfaces and frame used for the
collection of combustible matter after 36-months of controlled
post-fire in a Eucalyptus urograndis plantation in Sorriso, MT, Brazil.
Wherein: EA = Eucalyptus/Agriculture (a and d); EE = Eucalyptus/Eucalyptus (b
and d); EF = Eucalyptus/Forest (c and d).
Figura 2. Interfaces ambientais e quadrantes utilizados para a coleta
de material combustível em 36 meses de pós-queima controlada, em
plantio de Eucalyptus urograndis em Sorriso, MT, Brasil. Em que: (a) e (d)
Eucalyptus/Agriculture (EA); (b) e (d) Eucalyptus/Eucalyptus (EE); (c) e (d)
Eucalyptus/Forest (EF).
Figure 3. Classification of litterfall in Eucalyptus urograndis plantations
into: (a) leaves; (b) bark; (c) thin branches ≤0.7; (d) medium
branches (≥0.7 and ≤2.50); (e) thick branches (≥2.50); (f) storage of
the screened matter.
Figura 3. Triagem da serapilheira de Eucalyptus urograndis em classes:
(a) folhas; (b) casca; (c) galho fino ≤0,7; (d) galho médio (≥0,7 e
≤2,50); (e) galho grosso (≥2,50); (f) armazenamento do material
triado.
Figure 4. Percentages of the regenerated matter: (a) sampling frame
image; (b) image evaluation in the Adobe Photoshop Cs6 program;
(c) statistical specifications of the image, highlighting in red the
percentage of green matter collected in the interfaces with Eucalyptus
urograndis plantations.
Figure 4. Quantificação do percentual de material regenerado: (a)
imagem do quadrante amostral; (b) imagem avaliada no Software
Adobe Photoshop Cs6; (c) especificações da estatística da imagem,
destaque em vermelho do percentual de material verde coletado nas
interfaces de Eucalyptus urograndis.
Camargo et al.
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151
2.4. Phytosociological analysis of the burnable
herbaceous plants
The following phytosociological variables of burnable
herbaceous plants were analyzed: frequency (F); relative
frequency (Fr); density (D), which enables to determine the
quantity of plants of each species per unit of area; relative
density (Dr); abundance (A); relative abundance (Air);
importance index (IVI) (Mueller-Dombois; Ellenberg, 1974)
and relative importance index (IVIr) (Braun-Blanquet, 1979).
The variables Fr, Dr, and Air shows information on the
relation between the species found in the area, and are used
to obtain the IVI (Sena et al., 2019).
2.5. Statistical analyses
The data of the inventory were subjected to analysis of
variance (ANOVA) in a 3×4 factorial arrangement consisted
of litterfall and regenerated herbaceous plants, and when the
means showed differences, the Tukey's test at 5% probability
level was applied, both using the Sisvar statistical program
(FERREIRA, 2011).
The herbaceous plants were subjected to inferential
analyses following the specificities of the variables,
considering the wealth, abundance, and presence/absence of
species in the plant community. The analyses were carried out
in the R environment. Graphics were developed using the R
basic packages, and the R ggplot2 package (WICKHAM,
2016).
The rarefaction curves and extrapolation of species to the
community were based on the series of Hill, using the
iNEXT package (HSIEH et al., 2019), and compared
considering the periods with and without fire and the EA and
EF interfaces. The rarefaction indicates the wealth observed
as a function of the sampling effort used, and the
extrapolation.
A general linearized mixed model (GLMM) was
developed to determine the variation in wealth as a function
of periods of post-fire and control (VENABLES; RIPLEY,
2002). This methodology was chosen due to the existing
argument in the function that corrects the spatial data with
possible effect of autocorrelation. Thus, the plots were used
as random variable in the model to control the spatial
autocorrelation. The test for statistical significance was
carried out by analysis of type II square deviations (FOX;
WEISBERG, 2019).
The ordering of species of the plant community by non-
metric multidimensional scaling was carried out for the
abundance analysis (OKSANEN et al., 2019). Abundance
data tend to present high variation, therefore, locations that
presented no occurrence were excluded before the analyses,
and the transformation of Hellinger (OKSANEN et al.,
2019) was applied to equal the variance, since the calculation
of distances in matrices of abundance does not admit zero
values.
The dimensional solutions for abundance and
presence/absence data were used as dependent variable in
the statistical model, since they represent the highest
recovered variability of the plant community (abundance: r2adj
= 0.46, p < 0.001; presence/absence: r2adj = 0.62, p < 0.001).
Multivariate models of analysis of variance were
developed to determine whether abundance and
presence/absence variations (represented by dimensional
solutions - NMDS) are associated with the post-fire, post-fire
period, or interface.
3. RESULTS
3.1. Plantation Inventory Analysis
The forest community evaluated was very homogeneous,
considering that all plants had the same age (6.5 years). The
effects of prescribed fire and forest and agriculture interfaces
on the growth and development of the eucalyptus plantation
was low.
Regarding the number of trees, a mean of 16 trees per
plot was found in the areas with and without fire, with no
significant difference between plots. No significant
difference in tree survival rate was found between the
controls and areas with fire for the interfaces EA, EE, and
EF by the Tukey's test (Table 1).
The survival rate in the community was high, with
minimum rate of 77.5% (32 months) and maximum of
93.75% (36 months), both in the EF interface. Regarding the
mortality rate, the areas with fire showed similar results to
areas without fire, with no significant difference between
environmental interfaces, nor between the periods with and
without fire. The maximum mortality found was 22.50% (32
months), and the minimum was 6.25% (36 months), both in
the EF interface.
Regarding the CBH, the performance of the forest
community showed increases as expected, considering the
age of the plant, differing statistically only in the EA interface,
with circumference of 51.83 cm for the 36-month post-fire
and 65.95 cm for areas without fire.
Table 1. Total number of trees, percentage of living and dead trees, circumference at breast height (CHC) Eucalyptus. urograndis (Clone H13)
plantations in three envirnomental interfaces over 21-, 32-, and 36-month post-fire periods and without fire (control), Sorriso, MT, Brazil.
Tabela 1. Número de árvores total, percentual de árvores vivas e morta, circunferência a altura do peito (CAP) em área de Eucalyptus urograndis
- Clone H13 em três interfaces com 21, 32, 36 meses pós-queima e sem queima, em Sorriso, MT, Brasil.
Period Number of trees Percentage of living (%) Percentage of dead (%) CBH (cm)
EA EE EF EA EE EF EA EE EF EA EE EF
21 15.67 Aa
17.33 Aa
16.33 Aa
82.98 Aa
80.77 Aa
81.63 Aa
17.02 Aa
19.23 Aa 18.37 Aa
59.39 ABa
59.50 Aa 61.32 Aa
32 16.00 Aa
20.00 Aa
13.33 Aa
89.58 Aa
78.33 Aa
77.50 Aa
10.42 Aa
21.67 Aa 22.50 Aa
61.58 ABb
55.58 Aab
51.81 Aa
36 14.33 Aa
17.33 Aa
10.67 Aa
81.40 Aa
90.38 Aa
93.75 Aa
18.60 Aa
9.62 Aa 6.25 Aa
51.83 Aa 53.25 Aa 56.91 Aa
Without
fire 15.33 Aa
16.67 Aa
14.33 Aa
86.96 Aa
82.00 Aa
81.40 Aa
13.04 Aa
18.00 Aa 18.60 Aa
65.94 Bb 58.32 Aab
51.83 Aa
wherein: EA (eucalyptus/agriculture); EE (eucalyptus/eucalyptus); EF (eucalyptus/ remnant of native forest). * Means followed by equal uppercase letters
in the column and lowercase in the row do not differ by Tukey's test at 5% probability.
em que: EA (eucalipto/agricultura); EE (eucalipto/eucalipto); EF (eucalipto/remanescente de floresta nativa). * Médias seguidas por letras iguais maiusculas
na coluna e minusculas na linha, não diferente entre si pelo teste de Tukey a 5% de probabilidade.
Litterfall and herbaceous plants regeneration in planted forests at post prescribed fire
Nativa, Sinop, v. 11, n. 2, p. 148-160, 2023.
152
The analysis of variance for commercial height showed
no significant differences between post-fire periods and
controls for the EA and EF interfaces, presenting higher
commercial heights when compared to trees in the center of
the parcel (EE). The EE interface showed different
commercial heights from the EA and EF interfaces for areas
with fire in the 36- and 21-month post-fire periods, and EE
and EF differed in areas without fire (Table 2).
The same result was found for total height; periods with
and without fire did not differ from each other in the EA and
EF interfaces, whereas for EE, the total height for the 21-
month post-fire period (30.90 m) were different from that of
areas without fire (36.88 m).
The percentage of occupation of canopy in the absence
of fire showed differences between environmental interfaces;
EF had higher percentage (72.67%), differing from EE (65%)
and EA (63%). In areas with fire, the interface EE differed
statistically from the EF interface (Table 2).
3.2. Combustible matter analysis - Litterfall
The analyses in areas with and without fire showed no
significant differences in litterfall accumulation between the
EA, EE, and EF interfaces by the Tukey's test. The mean
accumulation in control areas with 6.5 years of age were 23.61
Mg ha-1 (EA), 18.95 Mg ha-1 (EE), and 23.76 Mg ha-1 (EF),
denoting decreases in the center of the community (Table 3).
The highest accumulation rate in the period of 21-month
post-fire period was found for the EF interface (14.77 Mg ha-
1). In the 32- and 36-month post-fire periods, the EA
interface presented higher accumulation, 20.70 Mg ha-1 and
20.71 Mg ha-1, respectively.
Table 2. Commercial to total height ratio and percentage of occupation of canopy in Eucalyptus. urograndis (Clone H13) plantations in three
envirnomental interfaces over 21-, 32-, and 36-month post-fire periods and without fire (control), Sorriso, MT, Brazil.
Tabela 3. Altura comercial/total e percentual de ocupação de copa em área de Eucalyptus. urograndis (Clone H13) em três interfaces com 21,
32, 36 meses pós-queima e Sem Queima (testemunha), Sorriso, MT, Brasil.
Período Commercial height (m)
Total height (m)
Canpoy percentagem occupation (%)
EA EE EF
EA EE EF
EA EE EF
21 35.61 Ab 28.98 ABa
38.91 Ab
39.99 Ab
30.90 Aa 42.26 Ab
67.66 ABab
61.33 Aa 72.33 Ab
32 34.42 Aa 31.83 ABa
33.75 Aa
39.21 Aa
35.57 ABa
38.88 Aa
73.67 Bb 68.00 ABab
66.00 Aa
36 37.98 Ab 27.28 Aa 37.27 Ab
39.92 Ab
30.66 Aa 40.12 Ab
61.33 Aa 70.33 Bb 66.00 Aab
Without fire
35.17 Aab 32.52 Ba 37.97 Ab
40.39 Aa
36.88 Ba 39.92 Aa
63.00 Aa 65.00 ABa 72.67 Ab
wherein: EA (eucalyptus/agriculture); EE (eucalyptus/eucalyptus); EF (eucalyptus/ remnant of native forest). * Means followed by equal uppercase letters
in the column and lowercase in the row do not differ by Tukey's test at 5% probability.
em que: EA (eucalipto/agricultura); EE (eucalipto/eucalipto); EF (eucalipto/remanescente de floresta nativa). * Médias seguidas por letras iguais maiusculas
na coluna e minusculas na linha, não diferente entre si pelo teste de Tukey a 5% de probabilidade.
Table 4. Classes of combustible matter (Mg ha-1) in Eucalyptus. urograndis (Clone H13) plantations in three envirnomental interfaces over 21-
, 32-, and 36-month post-fire periods and without fire (control), Sorriso, MT, Brazil.
Tabela 5. Classes de material combustível (Mg ha-1) em áreas de E. urograndis (Clone H13) em três interfaces com 21, 32, 36 meses pós-
queima, e áreas Sem Queima (testemunha), em Sorriso, MT, Brasil.
Period
Interface
Leaf Bark T1 T2 T3 MH Total
21
EL 4.56 Aa 4.99 Aa 1.73 Aa 2.04 Aa 0.25 Ab 0.41 Aa 13.98 Aa
EE 4.74 Aa 4.02 Aa 1.72 Aa 1.71 Aa 0.00 Aa 0.00 Aa 12.19 Aa
EF 4.58 Aa 2.27 Aa 1.71 Aa 3.42 Aa 0.00 Aa 2.79 Bb 14.77 Aa
32
EL 6.93 ABa 4.94 Aa 3.88 ABa 4.70 Aa 0.00 Aa 0.23 Aa 20.70 Aa
EE 6.37 Aa 2.27 Aa 2.92 Aa 3.39 Aa 0.00 Aa 0.63 Aab 15.59 Aa
EF 6.35 Aa 3.19 Aa 2.54 Aa 3.89 Aa 0.00 Aa 2.09 ABb 18.05 Aa
36
EL 6.03 Aa 3.18 Aa 4.81 Bb 6.67 Aa 0.00 Aa 0.03 Aa 20.71 Aa
EE 7.04 Aa 5.13 Aa 3.57 Aab 4.13 Aa 0.00 Aa 0.00 Aa 19.88 Aa
EF 6.34 Aa 2.62 Aa 2.66 Ab 4.56 Aa 0.00 Aa 2.05 ABb 18.22 Aa
Without fire
EL 11.26 Ba 3.72 Ab 4.44 Bb 4.13 Aab 0.00 Aa 0.06 Aa 23.61 Ab
EE 7.26 Aa 3.27 Ab 3.70 Ab 4.72 Aab 0.00 Aa 0.00 Aa 18.95 Aab
EF 9.19 Aa 3.01 Aab 3.36 Aab 7.64 Ab 0.00 Aa 0.56 Aa 23.76 Ab
wherein: EA (eucalyptus/agriculture); EE (eucalyptus/Eucalyptus); EF (eucalyptus/ remnant of native forest); T1 = thin branches with diameters (d) < 0.7
cm; T2 = medium branches 0.7 < (d) < 2.5 cm; T3 = thick branches (d) > 2.5 cm); EP = herbaceous plants, Mg ha-1 = megagrams per hectare. *Means
followed by the same uppercase letter in the columns or lowercase letter in the rows are not different from each other by the Tukey's test at 5% probability
level.
em que: EA (eucalipto/agricultura); EE (eucalipto/eucalipto); EF (eucalipto/remanescente de floresta nativa); T1: galhos finos diâmetro (d) < 0,7 cm); T2:
galhos médios 0,7 < (d) < 2,5 cm; T3 grossos (d) > 2,5 cm); MH. (Material Herbáceo), Mg ha-1 (megagramas por hectare). * Médias seguidas por letras iguais
maiusculas na coluna e minusculas na linha, não diferente entre si pelo teste de Tukey a 5% de probabilidade.
Leaves represented the highest fraction among the
litterfall classes, since areas without fire presented higher
deposition, standing out the EA interface, with 11.26 Mg ha-
1, representing 47.69% of all combustible matter (Figure 5a),
differing from the EE (7.26 Mg ha-1 / 38.31%) (Figure 5b)
and EF (9.19 Mg ha-1 / 38.68%) (Figure 5c) interfaces; EE
and EF were not different from each other.
A higher percentage of occurrence of the bark class was
found in the 21-month post-fire period in the EF (32.62%)
and EE (38.88%) interfaces (Figures 5a and b). No significant
difference in bark deposition after the fire was found by
Tukey’s test, presenting means (21-, 32-, and 36-month post-
fire periods) of 4.36 Mg ha-1 (EA); 3.81 Mg ha-1 (EE), and
2.69 Mg ha-1 (EF). These results were similar those in the
Camargo et al.
Nativa, Sinop, v. 11, n. 2, p. 148-160, 2023.
153
control period, which were 3.72 for EA, 3.27 for EE, and
3.01 Mg ha-1 for EF.
Thin branches were not much representative; however,
similar results were found for the EA interface between the
36-month post-fire period (4.81 Mg ha-1) and without fire
(4.44 Mg ha-1). Thick branches were found only in the EA
interface in the 21-month post-fire period, with 0.25 Mg ha-
1, representing 1.79% (Figure 5a).
The regeneration of herbaceous plants was lower when
compared to the litterfall class. The interface that presented
the highest regeneration percentage was the EF (Figure 5c),
with 18.89% (21 months), 11.58% (32 months) and 11.25%
(36 months). The regeneration in the EE interface occurred
only in the 32-month post-fire period. The proportion of
herbaceous plants was low in the controls, and was found in
the EA (0.25%) and EF (2.35%) interfaces, which did not
differ statistically from each other (Table 3).
The total deposition of combustible matter in the
remaining native forest fragment next to the eucalyptus
community was 13.66 Mg ha-1, with no significant difference
when compared to the total litterfall deposition of the E.
urograndis plantation (22.11 Mg ha-1) with 6.5 years of age.
Bark and thick branch depositions did not occur in the forest,
leaf deposition presented the highest fraction in the total
mean accumulation of combustible matter, with 9.92 Mg ha-
1, representing of 72.62% (Table 4 and Figure 6).
Figure 6. Class distribution of litterfall in Eucalyptus urograndis (Clone
H13) plantations and in a native forest fragment in the Cerrado-
Amazon transition in Sorriso, MT, Brazil. wherein: G1 = thin
branches with diameters (d) < 0.7 cm); G2 = medium branches 0.7
< (d) < 2.5 cm; G3 = thick branches (d) > 2.5 cm); EP = herbaceous
plants.
Figura 6. Distribuição da serapilheira por classes na floresta plantada
de Eucalyptus urograndis (Clone H13) e na Floresta Nativa
remanescente transição Cerrado-Amazônia, em Sorriso - MT. em
que, T1: galhos finos diâmetro (d) < 0,7cm); T2: galhos médios 0,7
< (d) < 2,5 cm; T3 grossos (d) > 2,5 cm); MH - Material Herbáceo.
Figure 5. Distribution of litterfall by classes within the interfaces eucalyptus/agriculture (a), eucalyptus/eucalyptus (b), and eucalyptus/
remnant of native forest (c) in areas with Eucalyptus urograndis (Clone H13) plantations in Sorriso, MT, Brazil, with different controlled post-
fire periods (21, 32, and 36 months) and without fire (77 months of age). wherein: T1 = thin branches with diameters (d) < 0.7 cm); T2 =
medium branches 0.7 < (d) < 2.5 cm; T3 = thick branches (d) > 2.5 cm); MH = herbaceous plants.
Figura 5. Distribuição da serapilheira por classes nas interfaces (a) eucalipto/agricultura; (b) eucalipto/eucalipto; (c) eucalipto/remanescente
de floresta nativa, das áreas de Eucalyptus urograndis (Clone H13) em Sorriso, MT, Brasil, com diferentes períodos pós-queima controlada (21,
32 e 36 meses), e sem queima (77 meses – idade do plantio). em que: as classes foram descritas como: T1: galhos finos diâmetro (d) < 0,7
cm); T2: galhos médios 0,7 < (d) < 2,5 cm; T3: galhos grossos (d) > 2,5 cm); MH (Material Herbáceo).
Table 6. Dry masso f the classes of combustible matter (Mg ha-1) in areas with E. urograndis (Clone H13) plantations and in a remnant of
native forest in Sorriso, MT, Brazil.
Tabela 7. Massa seca das classes de material combustível (Mg ha-1) em áreas de E. urograndis (Clone H13) e em um remanescente de floresta
nativa, em Sorriso, MT, Brasil.
Area Leaf Bark T1 T2 T3 MH Total
Eucalyptus urograndis 9.24 Aa 3.34 Aa 3.83 Aa 5.50 Aa 0.00 Aa 0.21 Aa 22.11 Aa
Forest 9.92 Aa 0.06 Aa 1.17 Aa 2.10 Aa 0.00 Aa 0.39 Aa 13.66 Aa
3.3. Combustible matter analysis - regenerated
herbaceous plants
The surveying of regeneration of green biomass in the
three interfaces in the post-fire periods and in the control
period (77 months) totalized 120 individuals, distributed into
17 genus, and one indeterminate, from 9 botanical families
(Table 5 and Figure 7). The regeneration of herbaceous plants
in post-fire areas was higher in the EA and EF interfaces,
predominating grass species from the Poaceae family,
whereas the bushy plants were more representative in the
areas without fire. Four species of the Poaceae family were
found in the experimental area, namely, Panicum maximum,
Paspalum maritimum, Panicum pernanbucensis, and Brachiaria
decumbens. P. maritimum presented higher abundance in all
interfaces and periods with and without fire (Figure 7a). The
more frequent species in the 21-month post-fire period in the
Litterfall and herbaceous plants regeneration in planted forests at post prescribed fire
Nativa, Sinop, v. 11, n. 2, p. 148-160, 2023.
154
interface EA was Machaerium sp. (33.3%); P. maritimum
(29.6%) presented the highest IVIr (Table 5). P. maximum and
P. maritimum represented more than half of all population
present in the EF interface, with frequency of 53.8%; P.
maximum presented the highest IVIr, with 38.3%. The
samples of the EE interface showed no regeneration of
herbaceous plants.
Table 5. Statistical variables of occurrence of regenerated species in areas with Eucalyptus urograndis (Clone H13) plantations post prescribed
fire in different environmental interfaces in Sorriso, MT, Brazil.
Tabela 5. Variáveis estatísticas da ocorrência de espécies regeneradas em áreas de Eucalyptus urograndis (Clone H13) pós-queimas prescritas
em diferentes interfaces ambientais, em Sorriso, MT, Brasil.
Burn Interface Period Specie Family Popular name Fr Dr Ar IVIr
(%)
Yes EL 21
Machaerium sp. Fabaceae Cipó 33.3 26.7 26.7 28.9
Panicum maximum Poaceae Capim-mombaça 22.2 13.3 13.3 16.3
Melampodium divaricatum Asteraceae Flor-amarela 11.1 6.7 6.7 8.1
Paspalum maritimum Poaceae Capim-pernambuco 22.2 33.3 33.3 29.6
Brachiaria decumbens Poaceae Brachiaria 11.1 20.0 20.0 17.0
Yes EF 21
Panicum maximum Poaceae Capim-mombaça 26.9 44.0 44.0 38.3
Paspalum maritimum Poaceae Capim-pernambuco 26.9 26.7 26.7 26.8
Blainvillea biaristata Asteraceae Picão 7.7 6.7 6.7 7.0
Melampodium divaricatum Asteraceae Flor-amarela 15.4 10.7 10.7 12.2
Mezilaurus itauba Fabaceae Itaúba 7.7 2.7 2.7 4.3
Machaerium sp. Fabaceae Cipó 15.4 9.3 9.3 11.4
Yes EL 32
Machaerium sp. Fabaceae Cipó 16.7 4.3 4.3 8.5
Paspalum maritimum Poaceae Capim-pernambuco 33.3 43.5 43.5 40.1
Melampodium divaricatum Asteraceae Flor-amarela 33.3 13.0 13.0 19.8
Panicum maximum Poaceae Capim-mombaça 16.7 39.1 39.1 31.6
Yes EE 32 Paspalum maritimum Poaceae Capim-pernambuco 100.0 100.0 100.0 100.0
Yes EF 32
Panicum maximum Poaceae Capim-mombaça 15.0 23.7 23.7 20.8
Rumex crispus Polygonaceae Paciência 10.0 6.8 6.8 7.9
Brachiaria decumbens Poaceae Brachiaria 10.0 13.6 13.6 12.4
Indeterminado
10.0 3.4 3.4 5.6
Paspalum maritimum Poaceae Capim-pernambuco 30.0 42.4 42.4 38.2
Solanum paniculatum Solanaceae Jurubeba 10.0 3.4 3.4 5.6
Vismia guianensis Hypericaceae Lacre-branco 5.0 1.7 1.7 2.8
Melampodium divaricatum Asteraceae Flor-amarela 5.0 3.4 3.4 13.6
Croton lobatus Euphorbiaceae Café-bravo 5.0 1.7 1.7 2.8
Yes EL 36
Melampodium divaricatum Asteraceae Flor-amarela 27.3 16.7 16.7 15.9
Panicum permanbucensis Poaceae Palha-branca 9.1 11.1 11.1 8.2
Panicum maximum Poaceae Capim-mombaça 9.1 5.6 5.6 5.3
Spermacoce palustres Rubiaceae Erva-de-lagarto 9.1 5.6 5.6 5.3
Machaerium sp. Fabaceae Cipó 27.3 44.4 44.4 30.4
Paspalum maritimum Poaceae Capim-pernambuco 18.2 69.7 134.6 17.2
Yes EE 36 Paspalum maritimum Poaceae Capim-pernambuco 100.0 100.0 100.0 100.0
Yes EF 36
Solanum paniculatum Solanaceae Jurubeba 13.0 5.4 5.4 7.9
Brachiaria decumbens Poaceae Brachiaria 26.1 51.8 51.8 43.2
Melampodium divaricatum Asteraceae Flor-amarela 4.3 1.8 1.8 2.6
Rumex crispus Polygonaceae Paciência 13.0 5.4 5.4 7.9
Blainvillea biaristata Asteraceae Picão 4.3 7.1 7.1 6.2
Paspalum maritimum Poaceae Capim-pernambuco 4.3 3.6 3.6 3.8
Panicum maximum Poaceae Capim-mombaça 8.7 3.6 3.6 5.3
Mezilaurus itauba Fabaceae Itaúba 8.7 5.4 5.4 6.5
Machaerium sp. Fabaceae Cipó 8.7 3.6 3.6 5.3
Spermacoce palustres Rubiaceae Erva-de-lagarto 4.3 7.1 7.1 6.2
lmperata brasiliensis Panicoideae Sapê 4.3 5.4 5.4 5.0
No EL 77 Spermacoce palustres Rubiaceae Erva-de-lagarto 50.0 75.0 75.0 66.7
Machaerium sp. Fabaceae Cipó 50.0 25.0 25.0 33.3
No EF 77
Paspalum maritimum Poaceae Capim-pernambuco 18.2 21.6 21.6 20.5
Mezilaurus itauba Fabaceae Itaúba 13.6 8.1 8.1 10.0
Melampodium divaricatum Asteraceae Flor-amarela 27.3 35.1 35.1 32.5
Rumex crispus Polygonaceae Paciência 4.5 2.7 2.7 3.3
Ageratum conyzoides Asteraceae Picão-roxo 4.5 2.7 2.7 3.3
Machaerium sp. Fabaceae Cipó 13.6 8.1 8.1 10.0
Cyperus iria Cyperaceae Tiririca 4.5 13.5 13.5 10.5
Scleria melaleuca Cyperaceae Campim-navalha 4.5 2.7 2.7 3.3
Panicum maximum Poaceae Capim-mombaça 4.5 2.7 2.7 3.3
Brachiaria decumbens Poaceae Brachiaria 4.5 2.7 2.7 3.3
wherein: EA (eucalyptus/agriculture), EE (eucalyptus/eucalyptus - central interface of the eucalyptus parcel); EF (eucalyptus/remnant of native forest); Fr
= relative frequency; Dr = relative density; Air = relative abundance; IVIr = Relative Importance Index.
em que: EA (eucalipto/agricultura), EE (parcela interface centro do talhão do eucalipto eucalipto/eucalitpto) e EF (parcela interface
eucalipto/remanescente de floresta nativa); Fr (Frequência Relativa); Dr (Densidade Relativa); Ar (Abundância Relativa); IVIr (Índice de Valor de Importância
Relativo).
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155
The most abundant species found for the 21-month post-
fire period was, in general, P. maximum, regardless of the
interface (Figure 7b). The 21-month post-fire period
presented higher occurrences of regeneration for EA and EF.
The most representative species found for 32-month post-
fire period in the EA interface was P. maritimum, with IVIr of
40.1%; this species presented the highest density and
abundance. Grouping the post-fire periods, the species P.
maritimum represented 100% (RF and IVIr) in the EE and
30% (RF) and 38.2% (IVr) in EF; thus, it can be described as
the most abundant species for the 32-month post-fire period
(Figure 7c).
Figure 7. Distribution of abundance as a function of sampled plant
species. Abundance is in logarithmic scale for a better view of the
community standard. The relations presented are: total community
(a), 21, 32-, and 36-month post-fire periods (b a d, respectively),
without fire for 77 months (e); and interfaces eucalyptus/agriculture
– EA (f) and eucalyptus/remnant of native forest– EF (g).
Figura 7. Distribuição da abundância em função das espécies
vegetais amostradas. Abundância está em escala
logarítmica para melhor visualizar o padrão da comunidade. As
relações apresentadas são: comunidade total (a), períodos pós-
queima de 21, 32 e 36 meses (b a d, respectivamente), sem queima
77 meses (e); e ainda, para interfaces eucalipto/agricultura (EA),
(f) e eucalipto/remanescente de floresta nativa (EF) (g).
Consequently, higher diversity of species was found for
the 36-month post-fire period; Machaerium sp. presented the
highest representativeness in the EA interface, with IVIr of
30.4%; only P. maritimum was found in the EE interface, with
100% frequency and IVIr; the grass species B. decumbens
presented the highest representativeness among the plants
sampled in the EF interface, with 26.1% frequency and
43.2% IVIr (Table 5). The most abundant species found for
the 36-month post-fire period was B. decumbens (Fig. 7d).
The species Spermacoce palustre and Machaerium sp. were
found in areas without fire and in the interface EA, with 50%
frequency and 66.7% and 33.3% IVr, respectively (Table 5).
The species with higher frequency in the EF interface was
Melampodium divaricatum, with 27.3% frequency and 32.5%
IVr. No species was found in the interface EE. Considering
the areas without fire, the most abundant species was M.
divaricatum (Figure 7e). When comparing the regeneration of
herbaceous plants in the interfaces, EA presented lower
regenerated plants than EF (Figure 7f-g).
The regeneration of herbaceous plants was higher in the
EF interface, regardless of the post-fire period (Figure 8);
higher proportions were found for the 21-month post-fire
period, with 55.4% for litterfall and 44.6% for regenerated
herbaceous plants.
The rarefaction curves developed showed lower wealth
of species in areas without fire and higher wealth in areas with
controlled fire (Figure 9). The post-fire periods and control
affected the abundance variation in the plant community and
the presence/absence was also affected by the community
interface (Table 6).
The similarity between areas with fire was low for the
regeneration of herbaceous plants, abundance, and
presence/absence (Figure 10). Similar results were also found
for post-fire periods and control, and community interfaces.
Figure 8. Percentage of area occupied by litterfall and herbaceous plants by post prescribed fire period. (a) EA [eucalyptus/agriculture]; (b)
EE [eucalyptus/eucalyptus – center of the parcel]; (c) EF [eucalyptus/remnant of native forest].
Figura 8. Percentual de área ocupada por serapilheira e material herbáceo por tempo pós-queimas controladas. (a) EA [eucalipto/agricultura];
(b) EE [eucalipto/eucalipto – centro do talhão]; (c) EF (eucalipto/remanescente de floresta nativa].
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Nativa, Sinop, v. 11, n. 2, p. 148-160, 2023.
156
Figure 9. Wealth of plant species found (continuous line) and extrapolated wealth (dotted line) as a function of the sample effort. Rarefaction
curves and extrapolations were calculated for (a) treatments with fire, (b) post-fire period, control without fire (77 months), and (c) interfaces
of the community. The shaded area represents the confidence interval.
Figura 9. Relação da riqueza de espécies vegetais observada (linha contínua) e riqueza extrapolada (linha pontilhada) em função do esforço
amostral. As curvas de rarefação e extrapolação foram calculadas para (a) tratamento de queima, (b) período pós-queima e testemunha (sem
queima – 77 meses), bem como (c) interfaces do povoamento. A área sombreada representa o intervalo de confiança.
Figure 10. Tridimensional spatial distribution of samples of abundance (Bray-Curtis distance) (a, c, e) and presence/absence of herbaceous
plants (Sørensen distance) (b, d, f), as a function of post-fire periods (a, b), post-fire period and control (c, d), and interface of the community
(e, f) in a E. urograndis (Clone H13) plantation.
Figure 10. Distribuição tridimensional das amostras no espaço da abundância (distância de Bray-Curtis) (a, c, e) e presença/ausência de
material herbáceo (distância de Sørensen) (b, d, f), em função dos períodos pós-queima (a, b), período pós-queima e testemunha (c, d) e
interface do povoamento (e, f) em área de E. urograndis (Clone H13).
Table 6. Probabilities associated to the abundance and presence/absence (represented by dimensional solutions - NMDS) variables as a
function of fire, post-fire periods, control, and interface of the community.
Tabela 6. Probabilidades associadas das variáveis abundância e presença/ausência (representadas pelas soluções dimensionais do NMDS)
em função de queima, períodos de pós-queima e controle (testemunha), e interface do povoamento.
Source of variation Abundance (NMDS)
Presence/Absence (NMDS)
gL Pillai-Trace P
gL Pillai-Trace P
Burn* 1 0.028 0.524
1 0.035 0.446
Post
-
burn period and
control
2 0.311 0.003
2 0.232 0.020
Settlement interface
2 0.149 0.118
2 0.205 0.036
Burn*Interface
1 0.077 0.113
1 0.029 0.508
Period*Interface
3 0.146 0.296
3 0.037 0.938
Waste
47
47
* Considering only the occurrence of fire, regardless of the post-fire period.
* Considerando apenas a ocorrência de queima, independentemente do período pós-queima.
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157
4. DISCUSSION
4.1. Forest inventory
The prescribed fire had no effect on the community
development, since the survival rate of trees was higher than
77%. This is connected to the low to moderate intensity of
prescribed fires on the surface of the sub-forest, which
seldom cause mortality of large-size trees (NOSS et al., 2006).
Studies with E. urograndis presented high survival rates,
varying from 91.8 to 95.9% in Roraima, and mortality rate of
18.92% in Mato Grosso (TONINI, 2006; MIRANDA et al.,
2019).
The mortality of eucalyptus tends to increase in plants
with age higher than 7 years, however other variables can be
associated, such as soil nutrition, weather conditions, water
availability, species adaptation, and inadequate silvicultural
practices (CAMPOE et al., 2016; CARMO et al., 2018;
MIRANDA et al., 2019).
Considering that the community analyzed had 6.5 years
of age, it was within the expected standards for survival rates
and mortality. Significant difference was found for CHC only
for the EA interface; however, this variation is common in
monospecific agriculture (VIERA et al., 2011). Therefore, it
was considered as normal for this age, since CHC and height
variables affect the wood volume, thus ensuring more
profitability in wood production for generation of energy.
The tree heights in the center of the community varied,
which is connected to the lower solar radiation incidence in
the center of the parcel; the trunk length growth depends on
light availability and trees in shading conditions tend to have
lower heights or be suppressed (BINKLEY et al., 2010).
Canopy percentage is also important for this study, since
the higher the canopy percentage, the lower the solar
radiation incidence (Viera et al., 2011) in the sub-forest. It can
affect the regeneration of herbaceous plants and decrease the
combustible matter availability. Thus, the application of
prescribed fire to the litterfall of the parcel is not a threat for
the plantation development. The mean values of variables
surveyed for the post-fire periods are similar those found in
the control.
4.2. Combustible matter - litterfall
The litterfall in areas with H13 clone are composed of
leaves, barks, thin branches, medium branches, and
herbaceous plants. The deposition of combustible matter
was, in general, similar in all interfaces, post-fire periods, and
areas without fire, showing that border and central areas of
the community do not affect the combustible matter
production, and the accumulation increases and tend to be
constant after 36 months. This similarity can be correlated
with the biomass decomposition, which is slow for
eucalyptus litterfall (SCHUMACHER et al., 2013).
The area without fire reached a maximum litterfall
production of 23.7 Mg ha-1 at 6.5 years of age; however, the
plantation cut cycle is between 7 and 7.6 years, thus, it stops
this combustible matter deposition. However, there are a risk
of fire before cutting, since combustible matter depositions
of 8 to 12 Mg ha-1 are high, 12 to 20 Mg ha-1 are very high,
and > 20 Mg ha-1 are extreme (MARSDEN-SMEDLEY,
2011).
Regarding the classification, leaves represented the
highest fraction of the litterfall combustible matter in all
interfaces and periods with and without fire. Previous studies,
when the forest community presented 5 years of age
(CARMO et al., 2018), found that the leaf fraction was also
the main litterfall formation fraction, varying from 51.76%
(EF) to 60.99% (EE). It still presented 40.0% of leaves at 6.5
years of age (LIMA et al., 2020a,b). Other studies state that
the leaf fraction stands out in the litterfall composition
(NETO et al., 2014; INKOTTE et al., 2015; SANTOS et al.,
2017), confirming the data found in the present study.
Although species of the Eucalyptus genus have several leaf
predators, they are grown in abundance, favoring fire
propagation, that threatens the plantation (SCHNEIDER,
2003). Thus, the adoption of controlled fire is required when
the area reach high leaf loads (> 0.7 cm) (MARSDEN-
SMEDLEY, 2011).
Barks are composed of dead tissues; its purpose is to
protect and provide resistance to plants and a defense against
abiotic and biotic threats (FERRENBERG; MITTON, 2014;
PAUSAS, 2015). The prescribed fire did not cause stress in
the trees, since the bark quantity in areas with fire were similar
that in areas without fire.
Regarding the branch classes, which present low
deposition, those with thickness < 0.7 cm were little
representative, whereas those > 2.5 cm presented higher
deposition in EA, representing 1.79% of deposition total of
litterfall. Thus, branches with equal or lower thickness than
this do not significantly affect fire propagation (MARSDEN-
SMEDLEY, 2011).
The regeneration of herbaceous plants in areas without
fire was lower than that in areas with fire, presenting higher
regeneration next to the agriculture and forest borders. Other
studies found similar results and attributed the absence or
presence of herbaceous plants due to the light availability,
which is higher in border areas (CIANCIARUSO et al., 2010;
DEVECCHI et al., 2020). Fire can be beneficial to stimulate
or facilitate several developmental phases of many of these
species, mainly herbaceous plants (WROBLESKI;
KAUFFMAN, 2003).
The combustible matter availability in the planted and
native forest presented no significant difference regarding the
litterfall deposition. However, the plantation age was close to
the cutting time and the mature native forest age was not
determined, denoting that eucalyptus plantations have high
deposition of combustible matter and had no enough time
for the decomposition of this matter due to its short cycle.
4.3. Regenerated burnable herbaceous plants
Fire can favor the reproduction of grass species from the
Poaceae family, whereas it does not favor bush species, since
it delays the regeneration time (CIANCIARUSO et al., 2010).
Although grass species present high number of leaves, alive
plants are not threat, since the higher the quantity of green
matter, the lower the fire propagation (ALVES et al., 2017).
However, it should be noted that the behavior of grasses does
not always follow what is exposed in this work, making it
possible to burn areas with this type of vegetation, even in
the rainy season, due to the large amount of combustible
material deposited below the green leaves. Furthermore, in
dry periods, they become highly flammable, increasing the
risk of fires and present higher temperatures over longer
times (GORGONE-BARBOSA et al., 2016).
Grass species have efficient photosynthetic performances
for the production and dispersion of diaspores and are highly
invasive (SOUZA et al., 2005; GORGONE-BARBOSA et
al., 2016). For example, P. maritimum is a species with high
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Nativa, Sinop, v. 11, n. 2, p. 148-160, 2023.
158
capacity of invade crop areas, form homogeneous colonies,
dominating the area over few years, and preventing the
regeneration and development of other species (SOUZA
FILHO, 2006).
The 21-months post-fire period presented higher
regeneration for EA and EF, since the germination of lianas,
herbaceous plants, and grass species in the first months after
the controlled fire can be due to the overcoming of dormancy
of seeds present in the litterfall and in the soil. These plants
present ecological succession characteristics typical of
pioneer species, with fast growth and development, and short
life cycle (Ricklefs, 2003), which explains the high occurrence
of these plants in sampled areas close to the forest and their
survival time in the area.
The most abundant species in areas without fire was M.
divaricatum; thus, fire can be beneficial for herbaceous plants,
by stimulating or facilitate several phases of their
development, and alter soil fertility (WROBLESKI;
KAUFFMAN, 2003; SILVA; BATALHA, 2008) found
higher organic matter, nitrogen, and clay contents in areas
with fire occurrences, which are rapidly absorbed by grass
species with shallow roots (CIANCIARUSO et al., 2010);
thus, this is probably one of the reasons for the abundance
of grass species in areas with controlled fire.
The regenerated herbaceous plants covered a larger area
in the EF interface, regardless of the post-fire period. This is
probably due to the presence of the native forest fragment in
the border of the eucalyptus plantation and the higher water
availability than in the other interfaces due to the proximity
with a lake. The regeneration in the EE interface was low in
the three periods analyzed because of the lowest seed
dispersion and the lower solar radiation in the center of the
parcel.
5. CONCLUSIONS
The eucalyptus plantations in the Cerrado-Amazon
transition region subjected to prescribed fire presented, after
36 months, presented similar litterfall quantity and
composition to areas without fire (77 months).
Leaves represented the highest combustible matter
fraction (litterfall) followed by medium branches, barks, thin
branches, herbaceous plants, and thick branches. This
accumulation over time can favor the intensity and
propagation of fire.
Thus, prescribed fire can be an important tool for the
managing of dry and alive combustible matter in sub-forest
of eucalyptus plantations in this transition region after four
years of implementation by decreasing the litterfall surface
layer, considering the state legislation, thus allowing the
prevention of forest fires of large proportions.
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Acknowledgments:
The Coordenação de Aperfeiçoamento de Pessoal de Nível
Superior (CAPES) for awarding the scholarship (Process
88882.459210/2019-01). The National Scientific and Technological
Development Council (Conselho Nacional de Desenvolvimento
Científico e Tecnológico CNPq) for the resources of the Research
Productivity Scholarship. To the members of the Research Group
"Environment and Plant Interactions". The Brasil Foods Company
(Lucas do Rio Verde Unit) for the release of the experimental area
and all UPL 03 employees.
Author Contributions: A.P.S.O.C. field data collection,
laboratory analysis, statistical analysis, initial writing; D.C.L. and
J.F.K. field data collection; R.A. - statistical analysis; A.P.S. -
conceptualization, methodology, research, validation, writing draft.
All authors read and agreed to the published version of the
manuscript.
Funding: Not applicable.
Institutional Review Board Statement: Not applicable.
Informed Consent Statement: Not applicable.
Data Availability Statement: Raw and analysed data can be
obtained by request to the corresponding Author by e-mail.
Conflicts of Interest: The authors declare that there is no conflict
of interests regarding the publication of this paper.