Nativa, Sinop, v. 9, n. 3, p. 318-326, mai./jun. 2021.

Pesquisas Agrárias e Ambientais

DOI: https://doi.org/10.31413/nativa.v9i3.12042 ISSN: 2318-7670

Crown morphometry for two valuable timber species from Miombo

woodland in Mozambique

Noé dos Santos Ananias HOFIÇO1*, Emanuel Arnoni COSTA2, Frederico Dimas FLEIG3,

César Augusto Guimarães FINGER3

1Department of Forest Engineering, Zambeze University – UniZambeze, Mocuba, Zambézia, Mozambique.

2Department of Forest Engineering, Federal University of Uberlândia, Monte Carmelo, MG, Brazil.

3Department of Forest Sciences, Federal University of Santa Maria, Santa Maria, RS, Brazil.

*E-mail: noe.hofico@gmail.com

(Orcid: 0000-0003-2554-4576; 0000-0002-0644-2403; 0000-0003-1683-3157; 0000-0003-1622-2399)

Recebido em 06/04/2021; Aceito em 12/07/2021; Publicado em 19/07/2021.

ABSTRACT:

Pterocarpus angolensis

DC and

Bobgunnia madagascariensis

(Desv.) J. H. Kirkbr. & Wiersema are two

hardwood species found in Miombo woodland. Crown size, being closely related to the photosynthetic capacity

of a tree, is an important parameter in studies of the growth of individual trees. In this sense, the present study

aimed to study the morphometric relationships of

P. angolensis

and

B. madagascariensis

as a resource to describe

the

morphometric

features

these

species.

Data

were

sampled

rectangular

plots

systematically distributed within the forest. In each plot, the diameter at breast height (DBH), height (h), crown

insertion point (cih) and four crown radii of all trees with DBH ≥ 10 cm were measured. Results indicated that

crown diameter and crown length of

P. angolensis

grow as DBH and height increase, the larger the crown, the

greater

the

trees

dimensions;

for

madagascariensis,

crown

features

have

shown

low

correlation

when

considering DBH. It was concluded that crown features influence on tree growth and are important measures

description

and

planning

silvicultural

activities

performed

natural

forests.

The

results

are

interest to forest managers since they make decisions about silvicultural operations.

Keywords:

crown dimensions; prediction models; umbila; pau-ferro; forest management.

Morfometria da copa para duas espécies madeireiras comerciais da floresta

de Miombo em Moçambique

RESUMO:

Pterocarpus

angolensis

Bobgunnia

madagascariensis

(Desv.)

Kirkbr.

Wiersema

são

duas

espécies

madeira

lei

encontradas

floresta

Miombo.

tamanho

copa,

está

intimamente

relacionado

capacidade

fotossintética

uma

árvore,

parâmetro

importante

nos

estudos

crescimento de árvores individuais. Nesse sentido, o presente estudo teve como objetivo estudar as relações

morfométricas de

P. angolensis

B. madagascariensis

como recurso para descrever as características morfométricas

dessas

espécies.

dados

foram

obtidos

parcelas

retangulares

distribuídas

sistematicamente na floresta. Em cada parcela, foram medidos o diâmetro à altura do peito (DAP), altura (h),

altura de inserção da copa (hic) e quatro raios da copa de todas as árvores com DAP ≥ 10 cm. Os resultados

indicaram que o diâmetro e o comprimento da copa de

P. angolensis

crescem com o aumento do DAP e da

altura; quanto maior a copa, maior dimensão das árvores, enquanto que para

B. madagascariensis, as características

copa

mostraram

baixa

correlação

considerar

DAP.

Concluiu-se

que

características

copa

influenciaram no crescimento das árvores e são importantes medidas de descrição e planejamento das atividades

silviculturais a serem realizadas na floresta. Estes resultados são de interesse dos manejadores florestais, pois

são eles que tomam decisões sobre as operações silviculturais.

Palavras-chave:

dimensões da copa; modelos preditivos; umbila; pau-ferro; manejo florestal.

1. INTRODUCTION

Pterocarpus angolensis DC (known as Umbila) and Bobgunnia

madagascariensis (Desv.) J. H. Kirkbr. & Wiersema (known as

Pau-ferro) are deciduous trees species of the Fabaceae family

found in Dry tropical forests in Southern and Eastern Africa,

including Miombo woodland (VAN WIK; VAN WIK,

2011). Miombo woodland is a vast African Dryland Forest

ecosystem covering close to 2.7 million km2 across Angola,

Democratic Republic of the Congo, Malawi, Mozambique,

Tanzania, Zambia and Zimbabwe. The Miombo woodland is

dominated by trees of the genera Brachystegia, Julbernardia and

Isoberlinia, in association with others species (CAMPBELL et

al., 2008). The woodland plays a crucial role in formal and

informal economies, supporting the livelihoods of millions of

rural and urban people, by providing important resources

such as timber, food, medicines, also play an important role

in the ecosystem dynamics, particularly with respect to

biodiversity, water, carbon and energy balance (KALABA et

al., 2014; RYAN et al., 2016).

In Mozambique, forestry is one of the 10 largest

industries in the country and accounted for a significants

Hofiço et al.

Nativa, Sinop, v. 9, n. 3, p. 318-326, mai./jun. 2021.

319

share of annual exports. For example, in 2019 the overall

forest sector accounted for approximately $570 million to the

gross domestic product (WORLD BANK, 2020). Despite

the large number of valuable tree species in Mozambique,

two species – P. angolensis and B. madagascariensis, represented

the bulk (44%) of timber harvest between 1999 and 2014, and

despite strict national-level Regulation of harvest, many are

concerned that harvest may be occurring in an unsustainable

manner (EGAS et al., 2013; MITADER, 2018).

Recently (March 2018), as a result of massive illegal

logging and exports the Government of Mozambique has

banned the harvest of two out of the six most exploited

timber species (e.g., Combretum imberbe and Bobgunnia

madagascariensis) and the export of Afzelia quanzensis, Millettia

stuhlmannii and Pterocarpus angolensis and has suspended the

development of new timber concession areas (REMANE;

THERRELL, 2019). Even with reforms in the forestry

sector, there remains doubt regarding strategies that could

allow interventions of sustainable management and ways to

optimize timber production in forests and raised the need for

their conservation.

Despite the economic value of these species, relatively

little research has focused on determining appropriate,

biological-based crown variables and morphometric features

schemes to help ensure that it is growth (including biomass),

productive potential of several native species in Mozambique

and make decisions about silvicultural operations

(GELDENHYUS, 2005; HOFIÇO et al., 2018; MITADER,

2018). The current demand for timber from these species in

the country, creates a need for tools for specific

measurements that support the management and use of the

existing stock.

A detailed investigation about crown features can

contribute to understanding the management of ecosystem

features such as forest productivity, biodiversity, and wildlife

habitats (WEISKITTELL et al., 2011). Thus, in order to

manage native forest species, it is necessary to know the

characteristics of tree dynamics throughout time, what

requires the description of morphometric relationships of

species to optimize silvicultural techniques (SEIFERT et al.,

2014; HESS et al., 2016).

Understanding morphometric relationships allows to

provide information about features of the adjustment of

crown morphology caused by competition for environmental

resources in forest communities (SEIFERT et al., 2014;

HESS et al., 2016), and studies about crown features (size and

architecture) are fundamental to model tree growth

(PRETZSCH, 2009). Modelling factors that influence on tree

growth, reflected on the variation of size and shape, allow to

establish strategies for the management of forest resources

(WEISKITTELL et al., 2011).

Considering individual trees, it allows to infer about each

one specifically by applying directly in forests and

populations of different ages, in trees of distinct social

positions because it mainly provides information about the

suitable living space according to tree size (SEIFERT et al.,

2014). Thus, size, structure, shape, and distribution of crowns

are intimately related to tree growth, growth strength and

productivity (GONZALEZ-BENECKE et al., 2014),

volume and biomass (MATE et al., 2014; JUCKER et al.,

2016), as well as wood quality, branch diameter, length of

growth ring, trunk conicity, knot features, core and sapwood

proportion (GONZALEZ-BENECKE et al., 2014; VON

HOLSBEECK et al., 2016).

Moreover, crown dimensions reflect the competition the

tree was subject to during its past growth (RUSSELL et al.,

2014, FU et al., 2017), this being relevant information for the

forester.

Models

that

describe

growth

regarding

individual

trees are usually

based on diameter at breast height, crown

length and its interactions with dendrometric variables, with

emphasis

the

morphometric

indexes

such

h/DBH

relationship,

crown

proportion,

salience

index,

coverage

index and formal of crown (COSTA et al., 2016; HESS et al.,

2016).

In light of this, the present study aimed to investigate the

dimensional

relationships

angolensis

and

madagascariensis

resource

for

the

description

morphometric

features

these

species

Miombo

woodland in Mozambique. The proposed model can be used

for

predictions

crown

morphometry

involving

these

important

species

and

provide

resources

for

the

country’s

management

plans

and

make

decisions

about

silvicultural

operations.

2. MATERIAL AND METHODS

2.1. Study area

The

study

was

performed

forest

concession

that

managed

Sotomane

Construction

and

Industry

Lda

(16°33'S

and

36°32'E,

16°49'S

and

36°47'E),

located

Mocuba District, Zambézia Province, in central Mozambique

(FIGURE

1).

The

main

activity

the

forest

concession

the

selective

cut

for

wood-producing

purposes.

However,

family subsistence agriculture is the predominant activity of

local

communities,

characterized

slash

and

burn

the

whole forest cover (clear cuts), resulting in annual fires and

degradation of these areas (HOFIÇO; FLEIG, 2015).

The

climate

the

region

(tropical

savanna)

according

the

Köppen

classification

system,

with

well-

defined seasons, dry winter from April to October, and wet

season from November to March. The annual mean rainfall

1200

and

mean

temperature

24.3

ºC.

Soils

are

predominantly

red

argisoils

hydromorphic

conditions

(MAE, 2005). Topography is slightly undulated between 200

m and 400 m above sea level.

Figure 1. Study area in Mocuba District, Zambézia Province,

Mozambique.

Figura 1. Área de estudo no Distrito de Mocuba, Província

da Zambézia, Moçambique.

Crown morphometry for two valuable timber species from Miombo woodland in Mozambique

Nativa, Sinop, v. 9, n. 3, p. 318-326, mai./jun. 2021.

320

2.2. Description of studied species

The Miombo woodland covers an area of 26.9 million ha

in Mozambique and corresponds to 67% of its total forest

area, being the main source of hardwood in the country

(MITADER, 2018). P. angolensis is a medium to large-sized

tree, up to 16 m tall that can reach 28 m. It has a rectilinear

and uniform trunk, a robust round-shaped crown, with a

dark-brown core and yellow-greyish sapwood, wood is hard

and moderately heavy, relatively easy to handle (Figure 2a).

As for B. madagascariensis, it is a small-sized tree varying

between 4 and 16 m tall, with rectilinear uniform trunk and

dense, robust and round-shaped crown (Figure 2b), its wood

is hard and very heavy, hard to be handled, and it shows no

significant difference in colour between core and sapwood

(BUNSTER, 2006; MOJEREMANE; LUMBILE, 2016).

Figure 2. Typical growth forms of tree species in Miombo

woodland, in Mocuba District, Mozambique, dry season 2020. (a)

Pterocarpus angolensis; and (b) Bobgunnia madagascariensis.

Figura 2. Formas de crescimento típicas das duas espécies árboreas

na floresta de Miombo, no Distrito de Mocuba, Moçambique,

estação seca de 2020. (a) Pterocarpus angolensis; e (b) Bobgunnia

madagascariensis.

Due to their physico-mechanical features such as

durability, resistance, density and colour, B. madagascariensis

and P. angolensis are species of high commercial value used in

the construction, naval and furniture industry, as well as

vehicle bodies, railroad ties, wood floor and decks, and

beehives (BUNSTER, 2006; ALI et al., 2008). Additionally,

parts of these species are widely used in traditional medicine

to treat diseases such as malaria, cornea ulcer, mycosis, fever,

and syphilis (STEVENSON et al., 2010; MOIEREMANE;

LUMBILE, 2016).

2.3. Data acquisition

Data were obtained from 60 plots of 20 x 50 m (1000 m2)

systematically distributed within a forest concession, with a

distance of 50 m between plots, and 100 m between lines.

For each objective tree, dendrometric and morphometric

variables of all trees with DBH ≥ 10 cm were measured,

totaling 171 trees of P. angolensis and 115 trees of B.

madagascariensis, covering the full range of diameters. The

measured variables were diameter at breast height (DBH) at

1.3 m above ground; height (h), corresponding to the

distance between ground level and crown top; commercial

height (ch), corresponding to the trunk with commercial

value; and height from the crown insertion point (cih)

corresponding to the distance between ground level and the

beginning of living crown. DBH was measured with a

precision dendrometric caliper (cm), height (m) with the

Blume-Leiss tool, and four crown radii in the cardinal points

north, south, east, and west, with a measuring tape and

compass. Crown length (cl) was obtained with the difference

between h and cih, in the expression [cl = h – cih]. Crown

diameter (cd) was calculated in meters with the mean crown

radium (cr), in the expression [cd = cr × 2] obtained from

four radii.

2.4. Data analysis

Descriptive statistics characterized the measured

variables. The diametric distribution was determined with the

class range of 5 cm, with the lower limit of the first class at

10.0 cm, and 14.9 cm as upper limit. For the analysis of the

morphometric relationships, the variables used were crown

length (cl), crown diameter (cd), the h/DBH relationship, or

slenderness coefficient (SC), the cd/cl relationship, known as

formal of crown (FC), the cd/DBH relationship, or salience

index (SI), and the cd/h relationship, or coverage index (CI),

according to the methodology described by Roman et al.

(2009), Hess et al. (2016) and Costa et al. (2016). From the

sampled data, the mean, minimal and maximum values of the

morphometric variables and dimensional relationships of P.

angolensis and B. madagascariensis were obtained, as shown in

Table 1.

To describe the dimensional characteristics (h, cih, ch, cl,

cd) according to DBH, the biometric model 1 was adjusted

in the non-linear model:

y = β0.exp (β1/x) + εi (01)

where: y – dimensional variable: h; cih; ch; cl; cd; x – DBH

(diameter at breast height, measured at 1.30 m above ground,

in cm); β0, β1 – estimated regression coefficient; εi – residual

error.

And in order to describe the relationship of the

morphometric variables (SC, FC, SI, CI), the biometric

model was adjusted in the non-linear model:

y = β0.Xβ1 + εi (02)

where: y – dimensional variable: SC; FC; SI; CI; x – DBH

(diameter at breast height, measured at 1.30 m above ground,

in cm); β0, β1 – estimated regression coefficient; εi – residual

error.

All statistics were processed with the SAS software

version 9.1 (SAS Institute Inc. 2004). For the performance of

the model, the coefficient of determination (R2), root mean

squared error (RMSE), and the graphic distribution of

residues in percentage (Table 2). The dimensional variable by

DBH and morphometric relationship of P. angolensis and B.

madagascariensis was used to draw graphs in eight figures using

the Microsoft Excel (2019).

Hofiço et al.

Nativa, Sinop, v. 9, n. 3, p. 318-326, mai./jun. 2021.

321

Table 1. Biometric characteristics of Pterocarpus angolensis and Bobgunnia madagascariensis in Miombo woodland in Mocuba

District, Mozambique.

Tabela 1. Características biométricas de Pterocarpus angolensis e Bobgunnia madagascariensis na floresta de Miombo no Distrito de

Mocuba, Moçambique.

Variable Unit

Pterocarpus angolensis

Bobgunnia madagascariensis

Mean

–

Range

Mean

–

Range

DBH

25.3 ± 12.9

10.0

6.7

19.4 ± 5.20

10.0

38.6

11.1 ± 3.10

5.60

17.6

11.0 ± 2.10

6.5

16.0

cih

5.70 ± 1.60

2.60

8.80

4.10 ± 1.00

2.00

6.0

4.50 ± 0.90

1.50

7.80

4.50 ± 1.20

2.00

7.0

5.40 ± 1.70

2.50

10.5

6.90 ± 2.00

2.00

12.0

6.70 ± 1.30

3.80

9.30

2.00 ± 0.50

0.80

3.6

0.48 ± 0.10

0.26

0.72

0.58 ± 0.12

0.31

0.90

2.61 ±

0.51

1.69

4.20

0.64 ± 0.29

0.21

2.20

61.0 ± 17.4

27.6

103.9

21.4 ± 5.60

7.70

36.0

1.24 ± 0.18

0.95

1.81

0.36 ± 0.09

0.17

0.63

where: SD – standard deviation; DBH – diameter at breast height, measured at 1.30 m above ground (cm); h – total height

(m); cih – height from the crown insertion point (m); ch – commercial height (m); cl – crown length (m); cd – crown diameter

(m); SC (slenderness coefficient) – h/DBH; FC (formal of crown) – cd/cl; SI (salience index) – cd/DBH; CI (coverage index)

– cd/h.

Table 2. Statistic criteria used to evaluate the adjusted models.

Tabela 2. Critérios estatísticos usados para avaliar os modelos

ajustados.

Statistical

criteria Expression

Coefficient of

determination

(3)



−



∑





−















∑

(



−



)













(Root Mean

Square Error

(4)

RMSE



(

−

)





(



−



)







Residual value

(%) (5)

Residual

value

(

)



−





100

Where: Yi – observed variable; Y

 – estimated variable; Y

 –

mean observed variable; n – number of observations; p –

number of estimated coefficients.

3. RESULTS

3.1. Population structure

The studied population of P. angolensis showed a typically

decreasing diameter distribution, with trees up to the class of

67.5 cm. B. madagascariensis also showed a decreasing

distribution, with a smaller number of trees in the first class,

probably resulting from the already established lack of natural

regeneration, what can lead to population decrease

throughout time (Figure 3). In the sample, 171 P. angolensis

(10.0 ≤ DBH ≤ 66.7 cm) and 115 B. madagascariensis (10.0 ≤

DBH ≤ 38.6 cm) were measured in 6 ha, corresponding to

28.5 and 19.2 trees.ha-1, respectively.

3.2. Morphometric relationship

The mean height for the two species was ≈ 11.0 m, with

a similar height range for both P. angolensis (5.6 m and 17.6 m)

and B. madagascariensis (6.5 m and 16.0 m). The measured

values of crown diameter varied between 3.80 ≤ cd ≤ 9.30

for P. angolensis, and 0.80 ≤ cd ≤ 3.6 for B. madagascariensis.

DBH also showed an expressive difference between the two

species, being 10.0 ≤ DBH ≤ 66.7 cm and 10.0 ≤ DBH ≤

38.6 cm, respectively, for P. angolensis and B. madagascariensis.

The other measured variables showed homogeneous

dimensions. The biometric model showed a specific

performance for each morphometric variable assessed as

dependent variable for P. angolensis and B. madagascariensis

(Table 3).

All P. angolensis regressions that describe the

morphometric variables according to DBH as well as the

regression coefficient (for α = 5%) were significant. The

lowest expression of the R2 coefficient was 0.13 in the ch

relationship, indicating the low adjusted in cl the increase of

tree diameter, also confirmed by the RMSE of 0.86 m. The

relationships of FC with R2 = 0.34 and CI with R2 = 0.35,

confirmed the lower dependence to DBH. The adjusted

regressions for the other variables had R2 values higher than

0.80 and significant coefficients.

Figure 3. Diameter distribution of Pterocarpus angolensis (grey

pillar) and Bobgunnia madagascariensis (black pillar) in Mocuba

District, Mozambique.

Figura 3. Distribuição diamétrica de Pterocarpus angolensis (pilar

cinza) e Bobgunnia madagascariensis (pilar preto) no Distrito de

Mocuba, Moçambique.

12,5 17,5 22,5 27,5 32,5 37,5 42,5 47,5 52,5 57,5 62,5 67,5

Density (n/ha)

Diameter class (cm)

P. angolensis

B. madagascariensis

Crown morphometry for two valuable timber species from Miombo woodland in Mozambique

Nativa, Sinop, v. 9, n. 3, p. 318-326, mai./jun. 2021.

322

The evaluated for B. madagascariensis showed similar

results for the variables FC and CI with a non-significant

regression coefficient (β1), indicating that there is no trend

data for the assessed equations. Though the morphometry of

P. angolensis and B. madagascariensis was adjusted with distinct

accuracy, the biometric model allowed to precisely describe

the mean development of morphometric variables of the two

species. The graphs in Figure 4, evidence the variables cd and

cih as the ones with the highest difference between species,

affecting the other morphometric indexes that contain these

variables.

Table 3. Estimated regression coefficients and statistics of adjustment and precision of the dimensional variables of Pterocarpus

angolensis and Bobgunnia madagascariensis, in Miombo woodland in Mocuba District, Mozambique.

Tabela 3. Coeficientes de regressão estimados e estatísticas de ajuste e precisão das variáveis dimensionais de Pterocarpus

angolensis e Bobgunnia madagascariensis, na floresta de Miombo no Distrito de Mocuba, Moçambique.

Variables

Species

F value

value > F

R²

RMSE

Pterocarpus angolensis

171

203

631

129

856

19426.1 <0.0001 0.94 0.76

(<0.

0001)

(<0.0001)

cih

362

117

056

7453.71 <0.0001 0.83 0.63

(<0.0001)

5.284

3.472

2170.16 <0.0001 0.13 0.89

(<0.0001)

9.998

8.429

17000.8 <0.0001 0.87 0.86

(<0.0001)

10.477

14.409

5929.56 <0.0001 0.85 0.67

(<0.0001)

167.379

0.402

11703.8 <0.0001 0.83 4.24

(<0.0001)

5.429

0.237

3405.19 <0.0001 0.34 0.42

(<0.0001)

330.491

0.553

7964.05 <0.0001 0.86 6.54

(<0.0001)

2.190

0.184

5923.58 <0.0001 0.35 0.15

(<0.0001)

Bobgunnia madagascariensis

115

17.165

8.201

2452.08 <0.0001 0.36 1.69

(<0.0001)

cih

5.270

4.598

957.65 <0.0001 0.07 1.01

(<0.0001)

(<0.006)

7.532

9.461

1111.61 <0.0001 0.25 1.03

(<0.0001)

(<0.006)

2.866

6.729

1355.75 <0.0001 0.18 0.41

(<0.0001)

12.199

10.549

887.67 <0.0001 0.24 1.77

(<0.0001)

274.6

0.529

2367.21 <0.0001 0.45 9.27

(<0.0001)

1.117

0.190

276.58 <0.0001 0.01 0.29

(<0.0375)

(<0.2451)

118.173

0.587

1413.26 <0.0001 0.37 4.37

(<0.0001)

0.463

0.078

1002.74 <0.0001 0.01 0.09

(<0.0001)

(<0.3653)

where: n – number of measured trees in the 6.0 ha sampled; h – total height, in m; cih – crown insertion height, in m; ch –

commercial height, in m; DBH – diameter at breast height, in cm; cl – crown length, in m; cd – crown diameter, in m; SC

(slenderness coefficient) – h/DBH; FC (formal of crown) – cd/cl; SI (salience index) – cd/DBH; CI (coverage index) – cd/h;

β0, β1 – estimated regression coefficients; R2 – coefficient of determination; RMSE – root mean squared error; p value > F –

probability value of the F-test; ( ) – probability value of t-test for estimated regression coefficients.

4. DISCUSSION

The negative exponential diametric distribution (Figure 3)

for P. angolensis suggests that the natural regeneration process

and the continued survival of the species in the forest are

ensured (CARO et al., 2005; DE CAUWER et al., 2014;

VAN HOLSBEECK et al., 2016; HOFIÇO et al., 2018).

According to Caro et al. (2005), this behaviour is due to the

fact that the species is adapted to survive and tolerate severe

environmental conditions such as fires and droughts.

Nevertheless, the unimodal diametric distribution of B.

madagascariensis can indicate the critical absence of natural

regeneration or plant mortality due to anthropic action,

which is recurrent in the region, as reported by Williams et al.

(2008) and Ryan; Williams (2011), in woodland recovery

during Miombo regeneration in Central Mozambique.

Hofiço et al.

Nativa, Sinop, v. 9, n. 3, p. 318-326, mai./jun. 2021.

323

Figure 4. Adjusted regressions lines according to the dimensional variables for Pterocarpus angolensis (solid line) and Bobgunnia

madagascariensis (dotted line) trees in Miombo woodland in Mocuba District, Mozambique.

Figura 4. Linhas de regressões ajustadas de acordo com as variáveis dimensionais para árvores de Pterocarpus angolensis (linha

contínua) e Bobgunnia madagascariensis (linha pontilhada) na floresta de Miombo no Distrito de Mocuba, Moçambique.

In addition to the anthropic action in the area, there is the

hypothesis that it occurs due to fires, which eliminate a

considerable number of regenerating trees when it goes

beyond human control, altering the structure of specific

populations in the Miombo ecosystem (WILLIAMS et al.,

2008; CHIDUMAYO, 2013; RIBEIRO et al., 2017). This

fact is integrated with studies in the Miombo ecosystem, in

which the negative influence of fires and the anthropic

disturbances in species ecological process – including natural

regeneration – are reported (CARO et al.; 2005; WILLIAMS

0 10 20 30 40 50 60 70 80

h (m)

DBH (cm)

(a)

0 10 20 30 40 50 60 70 80

cih (m)

DBH (cm)

(b)

0 10 20 30 40 50 60 70 80

cl (m)

DBH (cm)

(c)

0 10 20 30 40 50 60 70 80

cd (m)

DBH (cm)

(d)

100

0 10 20 30 40 50 60 70 80

DBH (cm)

(e)

0,0

0,5

1,0

1,5

2,0

2,5

3,0

3,5

0 10 20 30 40 50 60 70 80

DBH (cm)

(f)

100

0 10 20 30 40 50 60 70 80

DBH (cm)

(g)

0,0

0,2

0,4

0,6

0,8

1,0

1,2

1,4

1,6

0 10 20 30 40 50 60 70 80

DBH (cm)

(h)

Crown morphometry for two valuable timber species from Miombo woodland in Mozambique

Nativa, Sinop, v. 9, n. 3, p. 318-326, mai./jun. 2021.

324

et al., 2008; SYAMPUNGANI et al., 2016). In the specific

case of P. angolensis, it is possible to affirm that there still is

anthropic action for wood extraction in the study site.

Heights had a great significance in the understanding of

the features of these two species, which showed a high

structural complexity, reflected in the low R2 values of the

equations developed for the analysed morphometric

variables of B. madagascariensis. Sampled B. madagascariensis

trees were relatively young, with low variability of the

analysed dimensional characteristics.

These differences can be explained by the phenotypical

resilience of tree response to climate and other

environmental conditions such as altitude and soil features

(KALABA et al., 2013; SEIFERT et al., 2014), as well as the

action of fires, observed in the woodland, in which some

trees of B. madagascariensis had their trunks and crowns

damaged. It is important to mention that both B.

madagascariensis and P. angolensis are species of the same forest

formation and belong to the same family (Fabaceae) but to

different ecological groups: the first is a late-climax secondary

species whereas the latter is a pioneer species

(GONÇALVES et al., 2017; CHITECULO; SUROVY

2018), in other words, ecological strategies are different to

obtain better results for species growth and survival

(WILLIAMS et al., 2008; CHIDUMAYO, 2013). Chidumayo

(2019) report different strategies of trees in the Miombo

canopy where he found that most pioneer species grow

slower in the initial stages.

Crown length (cl) increased with DBH for both species

(Figure 3c), and B. madagascariensis was higher than P.

angolensis. This fact can be B. madagascariensis explained by the

shape of some B. madagascariensis trees observed in the studied

forest, which had multiple high stems and sparse crown,

contrary to the common feature of trees in the Miombo

woodland, which typically have flat and round umbel-shaped

crowns like P. angolensis (MATE et al., 2014; DE CAUWER

et al., 2014). Feldpausch et al. (2011) observed that the apical

growth speed of leafy species is higher for some species than

the mortality of branches in the crown basis, what results in

a higher crown proportion, being this variable an indicator of

tree vitality as well as an indicator of degree of competition.

The same increase was verified for crown diameter in

which P. angolensis and B. madagascariensis varied between 3.8

and 9.3 m, and 0.8 and 3.6 m, respectively (Table 1). It was

noted that B. madagascariensis showed a slight reduction in the

increase rate of crown diameter in higher DBH classes

(Figure 4d), what can indicate that a smaller space is needed

for side growth, consequently displaying a smaller area of

crown projection (ROMAN et al., 2009; SYAMPUNGANI

et al., 2016; HESS et al., 2016). P. angolensis showed an

increase in insertion height crown and crown diameter as

trees grew in diameter (Figure 4b and 4d). The high variability

in the dimensions of the crown can be related to the different

degrees of competition to which the tree is subjected

(SEIFERT et al., 2014; HESS et al., 2021).

However, this aspect, in the present work, is conflicting,

since the trees of P. angolensis and B. madagascariensis have little

influence from competition (MUGASHA et al., 2013; DE

CAUWER et al., 2014; MATE et al., 2015), as competition

becomes relevant only when there is light restriction

(PRETZSCH, 2009; ROMAN et al., 2009). Mugasha et al.

(2013) reported that as crowns grow their height increases,

and crowns are wider and need more space for growth, what

justifies the crown dimensions and tree height relationship.

Trees with large and healthy crowns are related to higher

growth rates as a result of the increase in the photosynthesis

rate (VON HOLSBEECK et al., 2016; FU et al., 2017).

Taking the slenderness coefficient (h/DBH) into

consideration, B. madagascariensis showed higher values than

P. angolensis (Table 1; Figure 4e). However, this feature tends

to decrease as DBH increases, indicating a higher stability of

trees, provided by the smaller DBH/total tree height

relationship, regardless of age (FELDPAUSCH et al., 2011;

MUGASHA et al., 2013). The decrease of the slenderness

coefficient is a positive physiological factor for stability since

trees with very high stems and small diameters are more

unstable, specially under the action of wind, which is

impossible to be controlled (MUGASHA et al., 2013;

SEIFERT et al., 2014) and can cause irreversible damage

such as crown breakage or tree fall (GONZALEZ-

BENECKE et al., 2014).

The FC with mean value of 2.61 for P. angolensis (Table 1)

indicates large crowns distinctive of the species, which has

ellipsoidal, flat or umbel-shaped crowns according to De

Cauwer et al. (2014). B. madagascariensis showed mean FC of

0.64, with slender and sparse crowns. The SI which expresses

how larger the crown diameter is than the DBH

(MUGASHA et al., 2013; HESS et al., 2021), was 61.0 for P.

angolensis¸ in other words, the crown diameter is 61 times

larger than the DBH – and 21.4 for B. madagascariensis (Table

1, Figure 4g).

A lower value of the SI means that the tree has a

proportionally higher crown surface area, making a more

efficient use of space, thus considering a given crown

projection area. Therefore, as trees grow within the forest,

this index can be used as a thinning indicator, establishing the

space to be cleared (GETZIN et al., 2011; GONZALEZ-

BENECKE et al., 2014).

The variable of the CI can also be used for species

management as it indicates the necessary space for the target

height (JUCKER et al., 2015; HESS et al., 2016). The mean

value for P. angolensis and B. madagascariensis was 1.24 and 0.36,

respectively (Table 1). This index showed an almost

curvilinear tendency as trees grew in height, as demonstrated

by this study (Figure 4h). This trend is a result of the small

increase of crown diameter with the increase of height in the

sampled classes, although no increase in height was observed.

The higher the value for this index, evidences that their

growth is larger in height than in DBH (FELDPAUSCH et

al., 2011).

We believe that for these activities to be successful,

growth data for valuable timber species such as those

presented in this study need to be widely available and we

hope this information can help inform the sustainable

management of timber in Mozambique.

5. CONCLUSIONS

There are significant and statistically precise relationships

for interdimensional and morphometric features of P.

angolensis, where crown diameter and crown length increase as

DBH and height increase, the larger the crown, the larger the

species growth, except for B. madagascariensis, whose crown

features were little related to DBH.

The high variability of canopy diameters probably occurs

due to the specific and adverse environmental conditions that

influence the growth of the species, confirming the resilience

characteristic of the same, high adaptation capacity. Crown

Hofiço et al.

Nativa, Sinop, v. 9, n. 3, p. 318-326, mai./jun. 2021.

325

features are the main factors that influence tree growth and

timber quality, and they are important information for forest

management measures, due to the simplicity and practicality

of application in natural forests.

This study can contribute through silvicultural

interventions that result in better increment rates and native

species growth in the context of management of individual

tree and conservation of species in a natural forest. The

results are relevant to conservation and sustainable

management for P. angolensis and B. madagascariensis trees in

central of Mozambique.

6. ACKNOWLEDGMENTS

We thank Sotomane concession staff and colleagues from

the Department of Forest Engineering at UniZambeze for

their support. Special thanks are due to Mr. Jaime Macuacua,

Marchante Assura and Miguel da Costa for important

contributions during the execution of this work. This

research was supported by the National Research Fund of

Mozambique (FNI: Project_12B/2018).

7. REFERENCES

ALI, A. C.; UETIMANE JUNIOR, E.; LHATE, I. A.;

TERZIEV, N. Anatomical characteristics, properties

and use of traditionally used and lesser-known wood

species from Mozambique: a literature review. Wood

Science and Technology, New York, v. 2, n. 6, p.

453-472, 2008. DOI: https://doi.org/10.1007/s00226-

008-0186-5

BUNSTER, J. Commercial timbers of Mozambique:

Technological Catalogue. Traforest Lda, Maputo,

Mozambique. 2006. 63p.

CAMPBELL, B.; ANGELSEN, A.; CUNNINGHAM, A.;

KATERERE, Y.; SITOE, A.; WUNDER, S. Miombo

woodlands: Opportunities and barriers to

sustainable forest management. Centre for

International Forestry Research (CIFOR), Bogor,

Indonesia. 2008. 41p.

CARO, T. M.; SUNGULA, M.; SCHWARTZ, M. W.;

BELLA, E. M. Recruitment of Pterocarpus angolensis in

the wild. Forest Ecology and Management,

Amsterdam, v. 219, n. 2-3, p. 69–175, 2005. DOI:

https://doi.org/10.1016/j.foreco.2005.07.004

CHIDUMAYO, E. N. Forest degradation and recovery in a

Miombo woodland landscape in Zambia: 22 years of

observations on permanent sample plots. Forest

Ecology and Management, Amsterdam, v. 291, p. 154-

161, 2013. DOI:

https://doi.org/10.1016/j.foreco.2012.11.031

CHIDUMAYO, E. N. Management implications of tree

growth patterns in Miombo woodlands of Zambia.

Forest Ecology and Management, Amsterdam, v. 436,

n. 1, p. 105-116, 2019. DOI:

https://doi.org/10.1016/j.foreco.2019.01.018

CHITECULO, V.; SUROVY, P. Dynamic Patterns of trees

species in Miombo Forest and management perspectives

for sustainable production - case study in Huambo

Province, Angola. Forests, Basel, v. 9, n. 6, p. 321, 2018.

DOI: https://doi.org/10.3390/f9060321

COSTA, E. A.; FINGER, C. A. G.; FLEIG, F. D. Influência

da posição social nas relações morfométricas de

Araucaria angustifolia. Ciência Florestal, Santa Maria, v.

26, n. 1, p. 225-234, 2016. DOI:

http://dx.doi.org/10.5380/rf.v47i4.49667

DE CAUWER, V.; MUYS, B.; REVERMANN, R.;

TRABUCCO, A. Potential, realised, future distribution

and environmental suitability for Pterocarpus angolensis

DC in southern Africa. Forest Ecology and

Management, Amsterdam, v.315, n. 1, p. 211-226, 2014.

DOI: https://doi.org/10.1016/j.foreco.2013.12.032

EGAS, A. Assessment of harvested volume and illegal

logging in Mozambican natural forests. Faculty of

Agronomy and Forest Engineering, Eduardo Mondlane

University. Maputo, Moçambique. 2013. 176p.

FELDPAUSCH, T. et al. Height-diameter allometry of

tropical forest trees. Biogeosciences, Hoboken, v. 8, p.

1081-1106, 2011. DOI: https://doi.org/10.5194/bg-8-

1081-2011

GELDENHUYS, C. J. Basic guidelines for silvicultural

and management practices in Mozambique. Report

FW-04/05, Forestwood, Pretoria, 2005. 78p.

GETZIN, S.; WORBES, M.; WIEGAND, T.; WIEGAND,

K. Size dominance regulates tree spacing more than

competition within height classes in tropical Cameroon.

Journal of Tropical Ecology, Cambridge, v. 27, n. 1, p.

93-102, 2011. DOI:

https://doi.org/10.1017/S0266467410000453

GONÇALVES, F. M. P.; REVERMANN, R.; GOMES, A.

L.; AIDAR, M. P. M.; FINCKH, M.; JUERGENS, N.

Tree species diversity and composition of Miombo

woodlands in South-Central Angola: A chronosequence

of forest recovery after shifting cultivation.

International Journal of Forestry Research, London,

v. 2017, n. 1, p. 1-13, 2017. DOI:

https://doi.org/10.1155/2017/6202093

GONZALEZ-BENECKE, C. A.; GEZAN, S. A.;

SAMUELSON, L. J.; CROPPER Jr., W. P.; LEDUC, D.

J.; MARTIN, T. A. Estimating Pinus palustris tree

diameter and stem volume from tree height, crown area

and stand-level parameters. Journal of Forest Research,

v. 25, n. 1, p. 43–52, 2014. DOI:

https://doi.org/10.1007/s11676-014-0427-4

HESS, A. F.; MINATTI, M.; COSTA, E. A.; SCHORR, L.

P. B.; ROSA, G. T. da; SOUZA, I. de A.; BORSOI, G.

A.; LIESENBERG, V.; STEPKA, T. F.; ABATTI, R.

Height-to-diameter ratios with temporal and

dendro/morphometric variables for Brazilian pine in

south Brazil. Journal of Forestry Research, v. 32, p.

191–202, 2021. DOI: https://doi.org/10.1007/s11676-

019-01084-8

HESS, A. F.; LOIOLA, T.; SOUZA, I. A. de;

NASCIMENTO, B. Morphometry of the crown of

Araucaria angustifolia in natural sites in southern Brazil.

Bosque, Valdivia, v. 37, n. 3, p. 603-611, 2016. DOI:

http://dx.doi.org/10.4067/S0717-92002016000300017

HOFIÇO, N. S. A.; COSTA, E. A.; FLEIG, F. D.;

NANVONAMUQUITXO, S. J. A. Regulation of the

diametric structure of the Miombo woodland using the

De Liocourt method in Mozambique. Nativa, Sinop, v.

6, n. 4, p. 407-414, 2018. DOI:

http://dx.doi.org/10.31413/nativa.v6i4.5396

HOFIÇO, N. S. A.; FLEIG, F. D. Diversity and structure of

Miombo woodlands in Mozambique using a range of

sampling sizes. Journal of Agricultural Science and

Technology, Tarbiat, v. 5, n. 10, p. 679-690, 2015. DOI:

10.17265/2161-6264/2015.10.005

Crown morphometry for two valuable timber species from Miombo woodland in Mozambique

Nativa, Sinop, v. 9, n. 3, p. 318-326, mai./jun. 2021.

326

JUCKER, T.; BOURIAUD, O.; COOMES, D. A. Crown

plasticity enables trees to optimize canopy packing in

mixed-species forests. Functional Ecology, Oxford, v.

29, p. 1078-1086, 2015. DOI:

https://doi.org/10.1111/1365-2435.12428

KALABA, F. K.; QUINN, C. H.; DOUGILL, A. J.; VINYA,

R. Floristic composition, species diversity and carbon

storage in charcoal and agriculture fallows and

management implications in Miombo woodlands of

Zambia. Forest Ecology and Management,

Amsterdam, v. 304, p. 99–109, 2013. DOI:

https://doi.org/10.1016/j.foreco.2013.04.024

KALABA, F. K.; QUINN, C. H.; DOUGILL, A. J. The role

of forest provisioning ecosystem services in coping with

household stresses and shocks in Miombo woodlands,

Zambia. Ecosystem Services, v. 5, p. 143-148, 2014.

DOI: https://doi.org/10.1016/j.ecoser.2013.07.008

MAE. Perfil do distrito de Mocuba. Província da

Zambézia. Ministério da Administração Estatal. Série

Perfis Distritais, Maputo, Mozambique. 2005. 50p.

MALMER, A. General ecological features of Miombo

woodlands and considerations for utilization and

management. p. 34-42. 2007. (Working Papers of the

Finnish Forest Research Institute, v. 50).

MATE, R.; JOHANSSON, T.; SITOE, A. Biomass

equations for tropical forest tree species in Mozambique.

Forests, Basel, v. 5, p. 535-556, 2014. DOI:

https://doi.org/10.3390/f5030535

MATE, R.; JOHANSSON, T.; SITOE, A. Stem Volume

Equations for Valuable Timber Species in Mozambique.

Journal of Sustainable Forestry, v. 34, n. 8, p. 787-806,

2015. DOI:

http://dx.doi.org/10.1080/10549811.2015.1039043

MITADER. Inventário Florestal Nacional. Ministry of

Land, Environment and Rural Development, Maputo,

Mozambique. 2018. 118p.

MOJEREMANE, W.; LUMBILE, A. U. A review of

Pterocarpus angolensis DC. (Mukwa) an important and

threatened timber species of the Miombo

woodlands. Research Journal of Forestry, v. 10, n. 1, p.

8-14, 2016. DOI: https://doi.org/10.3923/rjf.2016.8.14

MUGASHA, W. A.; BOLLANDSÅS, O. M.; EID, T.

Relationships between diameter and height of trees in

natural tropical forest in Tanzania. Southern Forests: a

Journal of Forest Science, Makhanda, v. 75, n. 4, v. 221-

237, 2013. DOI:

https://doi.org/10.2989/20702620.2013.824672

PRETZSCH, H. Forest dynamics, growth and yield.

Heidelberg: Springer Verlag Berlin. Germany, 2009.

664p.

REMANE, I. A. D.; THERRELL, M. D. Tree-ring analysis

for sustainable harvest of Millettia stuhlmannii in

Mozambique. South African Journal of Botany,

Pretoria, v. 125, p. 120-125, 2019. DOI:

https://doi.org/10.1016/j.sajb.2019.07.012

RIBEIRO, N. S.; CANGELA, A.; CHAUQUE, A.;

BANDEIRA, R. R.; RIBEIRO-BRROS, A. I.

Characterisation of spatial and temporal distribution of

the fire regime in Niassa National Reserve, northern

Mozambique. International Journal of Wildland Fire,

Rosyn, v. 26, n. 12, p. 1021–1029, 2017. DOI:

https://doi.org/10.1071/WF17085

ROMAN, M.; BRESSAN, D. A.; DURLO, M. A. Variáveis

morfométricas e relações interdimensionais para Cordia

trichotoma (Vell.) Arráb. ex Steud. Ciência Florestal,

Santa Maria, v. 19, n. 4, p. 473-480, 2009. DOI:

http://dx.doi.org/10.5902/19805098901

RYAN, C. M.; PRITCHARD, R.; McNICOL, I.; OWEN,

M.; FISHER, J. A.; LEHMANN, C. Ecosystem services

from southern African woodlands and their future under

global change. Philosophical Transaction B, London,

v. 371, ID 20150312, 2016. DOI:

https://doi.org/10.1098/rstb.2015.0312

RYAN, C. M.; WILLIAMS, M. How does fire intensity and

frequency affect Miombo woodland tree populations and

biomass? Ecological applications, Washington, v. 21,

n. 1, p. 48–60, 2011. DOI: https://doi.org/10.1890/09-

1489.1

SEIFERT, T.; SEIFERT, S.; SEYDACK, A.; DURRHEIM.

G.; GADOW, K. V. Competition effects in an

Afrotemperate forest. Forest Ecosystems, New York,

v. 1, n. 13, p. 1-15, 2014. DOI:

https://doi.org/10.1186/s40663-014-0013-4

SHIRIMA, D.; TOTLAND, O.; MUNISHI, P. K. T.; MOE,

S. R. Does the abundance of dominant trees affect

diversity of a widespread tropical woodland ecosystem in

Tanzania? Journal of Tropical Ecology, Cambridge, v.

31, n. 4, P. 345-359, 2015. DOI:

https://doi.org/10.1017/S0266467415000231

STEVENSON, P. C.; NYIRENDA, S. P.; VEITCH, N. C.

Highly glycosylated flavonoids from the pods of

Bobgunnia madagascariensis. Tetrahedron Letters,

Elmsford, v. 51, n. 36, p. 4727-4730, 2010. DOI:

https://doi.org/10.1016/j.tetlet.2010.07.013

SYAMPUNGANI, S.; GELDENHUYS, C. J.; CHIRWA, P.

W. Regeneration dynamics of Miombo woodland in

response to different anthropogenic disturbances: forest

characterisation for sustainable management.

Agroforestry Systems, Dordrecht, v. 90, p. 563-576,

2016. DOI: https://doi.org/10.1007/s10457-015-9841-7

VAN WYK, B.; VAN WYK, P. Field guide to trees of

Southern Africa. Cape Town: Struik publishers, 2011.

536p.

VAN HOLSBEECK, S.; CAUWER, V. de; RIDDER, M. de;

FICHTLER, E.; BEECKMAN, H.; MERTENS, J.

Annual diameter growth of Pterocarpus angolensis

(Kiaat) and other woodland species in Namibia. Forest

Ecology and Management, Amsterdam, v. 373, n. 1, p.

1-8, 2016. DOI:

https://doi.org/10.1016/j.foreco.2016.04.031

WEISKITTELAR, H.; KERSHAWJA, D. W.; VANCLAY,

J. K. Forest growth and yield modeling. Chichester:

John Wiley & Sons Ltda, 2011. 415p.

WORLD BANK. Trading economics. Mozambique

GDP 1980-2019. 2020. Disponível em:

https://tradingeconomics.com/mozambique/gdp.