BioRisk 20: | 5a | 63 (2023) Apeer-reviewed open-access journal

doi: 10.3897/biorisk.20.97534 RESEARCH ARTICLE & B} Ke) RP IS k

https://biorisk.pensoft.net

Forest habitats of Godech Municipality,
Western Bulgaria

Borislav Grigorov', Nikolay Velev’, Assen Assenov',
Momchil Nazarov’, Beloslava Genova’, Kiril Vassilev?

| Faculty of Geology and Geography, Department of Landscape Ecology and Environmental Protection,
Sofia University “St. Kliment Ohridski”, Sofia, Bulgaria 2 Institute of Biodiversity and Ecosystem Research,
Department of Plant and Fungal Diversity and Resources, Bulgarian Academy of Sciences, Sofia, Bulgaria

Corresponding author: Borislav Grigorov (borislav.g.grigorov@gmail.com)

Academic editor: K. Danova | Received 14 November 2022 | Accepted 29 December 2022 | Published 15 May 2023

Citation: Grigorov B, Velev N, Assenov A, Nazarov M, Genova B, Vassilev K (2023) Forest habitats of Godech
Municipality, Western Bulgaria. In: Chankova S, Danova K, Beltcheva M, Radeva G, Petrova V, Vassilev K (Eds) Actual
problems of Ecology. BioRisk 20: 153-163. https://doi.org/10.3897/biorisk.20.97534

Abstract

The current study aims at revealing the forest habitat diversity of Godech Municipality, according to the
EUNIS habitat classification. Initial data was collected from the Ministry of Environment and Water
and the Forestry Management Plans. Subsequently, 418 vegetation plots (relevés) and 3422 verification
points were collected during the fieldwork seasons of 2019 and 2020. The research territory is situated in
Western Bulgaria in close proximity to the country’s border with the Republic of Serbia. Forests cover a
total of 144.85 km*. Their phytocoenoses are dominated by Fagus sylvatica L. (59.22 km?), Quercus cerris
L. (14.85 km’), Carpinus betulus L. (4.94 km’), Quercus dalechampii Ten. (2.39 km*), Q. frainetto Ten.
(2.99 km’). There are plantations with Pinus nigra J. E Arnold (20.87 km’), P sylvestris L. (16.06 km’)
and Picea abies H. Karst (11.65 km”) also. Forests are experiencing some major threats, such as logging,
pollution and fires.

Keywords
EUNIS, GIS, habitat mapping, syntaxa, vegetation and habitat diversity

Introduction

The role of forests in the functioning of our planet is indispensable. They hold one of
the keys for the reduction of human’s ecological footprint. Forests provide a vast array

Copyright Borislav Grigorov et al. This is an open access article distributed under the terms of the Creative Commons Attribution License (CC
BY 4.0), which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.

154 Borislav Grigorov et al. / BioRisk 20: 153-163 (2023)

of ecosystem services (Garcia-Nieto et al. 2013; Aznar-Sanchez et al. 2018; Acharya et
al. 2019). The sustainability issue is also tied tightly to a forest’s structure and function-
ing. Many forest habitats in Bulgaria are protected, but poorly managed in general.
They are included in the Natura 2000 network and watched over by Council Directive
92/43/EEC of the European Union. Still more research is needed to unveil their full
significance for our well-being. More awareness has to be raised for their overall protec-
tion, but not only on paper. Despite the lack of governmental acknowledgement of the
importance of the forest ecosystem in Bulgaria, we still possess around 30% of forested
territory. The authors share the view that forest habitats have to be mapped, comply-
ing with all current trends at the perspective of the EUNIS classification, striving for
habitat monitoring and protection (Chytry et al. 2020).

Forests in western Bulgaria have been investigated by a number of scientists (Yor-
danov 1924; Minchev 1938; Florov 1952; Garelkov 1973; Filipovich 1981; Filipovich
and Antonov 1996; Dodev and Popov 2011). Tzonev et al. (2006, 2019), Tashev et al.
(2010), Dimitrov and Petrova (2014) played their role in forest habitat research.

The present study represents a continuation of the habitat investigations in West-
ern Bulgaria, based on the EUNIS classification (Grigorov et al. 2022a). Habitats in
Godech and Dragoman Municipality have already been studied by Grigorov et al.
(2021a, b, 2022a, b). The creation of a habitat map of forests in Godech Municipality,
based on the EUNIS classification, will provide more data to policy makers and this is
a main aim of the current work.

Methods

Godech Municipality covers ca. 375 km? (Fig. 1). The territory is situated in the west-
ern part of Bulgaria. It borders the municipalities of Berkovitsa and Varshets to the
north, Svoge municipality on the east, Dragoman and Kostinbrod municipalities on
the south. The orogenesis has led to the formation of the following mountain ranges:
Berkovska Mountain, Ponor Mountain, Vidlich, Vuchibaba and Chepun Mountain.
Godech Valley, also known as Zaburge, is located in-between. The highest peak is Sre-
barna (1931.3 m), situated in Berkovska Mountain. More than 50% of the territory
has an elevation between 1000 and 1600 m above sea level. The geological features
include carbonate rocks (limestones, dolomitic limestones, dolomites) — a prerequisite
for development of the karstification process. Breccias, conglomerates and sandstones
are present, as well. Intrusive rocks and alluvial deposits may also be found (Zagorchev
et al. 1990). The main river is Nishava with its tributary — Arakul River. The wide va-
riety of geographical conditions has led to the formation of different soil types, such as
Cambisols, Luvisols, Alluvisols and vegetation communities.

The fieldwork seasons of 2019 and 2020 were used for collection of 418 relevés
following the Braun-Blanquet approach (Braun-Blanquet 1965) and 3422 verification
field points (Fig. 1). All data collected in the field was applied in order to build a pre-
cise habitat map of the area. All collected relevés contributed to the Balkan Vegetation

Forests habitats of Godech Municipality, Western Bulgaria 155

ie A

\_-——_Georgi Damyanovo
a,
~,

Berkovitsa

Serbia

a Natura zones

Villages

Fieldwork points

Kostinbrod Neighbouring countries

Municipalities

Figure |. Forest vegetation relevés and verification points collected in Godech Municipality.

Database (Vassilev et al. 2020) and Balkan Dry Grassland Database (Vassilev et al.
2012). All relevés were plotted in homogenous areas of forest communities and were
subsequently assigned to relevant habitat types. Habitat types were related subsequent-
ly to the revised version of the EUNIS system (Chytry et al. 2020).

The EUNIS habitat types were determined with the help of the classification
expert system EUNIS-ESy (Chytry et al. 2020) integrated into JUICE 7.1 software
(Tichy 2002). All defined habitat groups have had their diagnostic, dominant and
constant species determined, following Chytry et al. (2020). Every semi-natural habi-
tat type was classified to alliance level according to Mucina et al. (2016). Associations
were determined based on the expert knowledge and available literature sources for the
country (Tzonev et al. 2006, 2019).

Mapping was done using the ArcGIS 10.6 software package. Spatial data was col-
lected in the field using GPS device Juno BS by Trimble and was later laid over the
most recent orthophoto images available. The habitat map was created by the help of
the “Intersect tool” by combining the layers, containing forestry data from Forestry
Management Plans, as well as data about agricultural areas and habitat data from habi-
tat mapping of NATURA 2000 in Bulgaria. Later, the “Cut polygon” tool was used in
order to precisely modify the polygon geometry. All polygons were outlined manually
using all the field collected data as well as the orthophoto images. The habitat map was
elaborated in scale 1:5000.

156 Borislav Grigorov et al. / BioRisk 20: 153-163 (2023)

/ Stenintsi se

ase i .: by} cry (Ta
go Meda we: bt® on
eet AiFie3,** P

= E

Figure 2. EUNIS forest habitat types in Godech Municipality.

Results

All studied forest types in Godech Municipality were related to 7 EUNIS habitat types
(Fig. 2), which cover an area of 144.85 km’.

TIE Carpinus and Quercus mesic deciduous forest

Abiotic characteristic: This habitat type covered an area of 12.20 km’. It was located
on slopes with humid conditions mainly in the mountains of Chepun, Vuchibaba
and Berkovska Mountain predominantly in the hypsometric belts between 600 and
1000 m a.s.l. on slightly inclined slopes (10—15°) predominantly with northern and
western components. Limestones, dolomites and marls were present. Soils were aver-
agely deep. This habitat type was presented by 78 polygons (map units). The polygon’s
area was in the range of 0.0007—2.14 km’.

Species composition and vegetation structure: T1E habitat type included
monodominant or mixed forests with a closed horizontal structure and a total cover of
90-100%. Carpinus betulus L. orland Quercus petraea agg. dominated the tree layer,
which had a cover of 85—100%. Fagus sylvatica L., Acer campestre L., Tilia platyphyllos
Scop., Quercus cerris L. and Sorbus torminalis Crantz were also present. The shrub layer
had a cover of 20-40% and was formed by the same species of the tree layer as well
as Ligustrum vulgare L. and Corylus avellana L. The herb layer also had poor species

Forests habitats of Godech Municipality, Western Bulgaria 157

composition and the most frequent species were Festuca heterophylla Lam., Melica
uniflora Retz., Poa nemoralis L., Aremonia agrimonoides (L.) DC. Its cover was about
45-65%. The habitat type falls within class Carpino-Fagetea, order Fagetalia sylvaticae
and the alliances Carpinion betuli and Fagion sylvaticae s.\. This vegetation represents
9170 Galio-Carpinetum oak-hornbeam forests, according to the Habitat Directive.

TIH Broadleaved deciduous plantation of non-site native trees

Abiotic characteristic: This habitat included plantations dispersed throughout the
municipality and covered a territory of 1.21 km’, mainly in Berkovska Mountain at
600-1000 m a.s.l. on slopes with various distribution. The bedrock types were repre-
sented mainly by limestone and dolomites and the soils were shallow to moderately
deep. This habitat type was presented by 12 polygons. The polygon’s area was in the
range of 0.00000001-0.70 km’.

Species composition and vegetation structure: Two tree species dominated the
plantations: Robinia pseudoacacia L. and Quercus rubra L. ‘The total vegetation cov-
er in the studied polygons was 85-95%. Prunus cerasifera Ehrh., Pyrus pyraster (L.)
Burgsd., Malus domestica Borkh., Carpinus betulus L., Acer campestre L., Quercus cerris
L., Q. frainetto Ten., Q. petraea agg. were also present in the tree layer. The shrub layer
was well-developed and had a cover of 25-50% and was formed by the same species of
tree layer as well as Crataegus monogyna Jacq., Prunus spinosa L., Euonymus verrucosus
Scopoli, Rosa canina L., Rubus caesius L., Fraxinus ornus L., Carpinus orientalis Mill.
and Cornus mas L. The herb layer of Robinia pseudoacacia L. plantations was well-
developed with cover 90-100%. Bromus sterilis L. was the dominant species. Other
common species were Galium aparine L., Myrrhoides nodosa (L.) Cannon, Chelidonium
majus L. Quercus rubra L. forests had a very poor species composition and the herb
layer had a very low cover (up to 10-15%). Robinia pseudoacacia L. plantations belong
to association Bromo sterilis-Robinietum, alliance Balloto nigrae-Robinion pseudoacaciae,
order Chelidonio-Robinietalia pseudoacaciae and class Robinietea.

T3N *Coniferous plantation of site-native trees

Abiotic characteristic: This habitat type was distributed in all parts of the municipal-
ity and included planted coniferous forests at the hypsometric belts 200-600, 600—
1000 and 1000-1600 m a.s.l. on slopes with various distribution. It covered an area of
41.97 km’. Sedimentary and magmatic rocks were at the basis of shallow to averagely
deep Chromic Luvisols and Rendzic Leptosols. This habitat type was presented by 246
polygons. The polygon’s area was in the range of 0.0009-5.24 km’.

Species composition and vegetation structure: The main tree species were Pinus
sylvestris L., PR nigra J. E Arnold and Picea abies H. Karst. The tree layer was well-
developed with a cover of 85-100%. The horizontal vegetation structure was closed
in the Pinus sylvestris L. stands and semi-open in the Pinus nigra J. F. Arnold stands.
Other typical tree species were: Fagus sylvatica L., Quercus spp., Acer pseudoplatanus L.

158 Borislav Grigorov et al. / BioRisk 20: 153-163 (2023)

The shrub layer of Pinus nigra J. F. Arnold and P sylvestris L. plantations included Rosa
canina L., Rubus spp., Crataegus monogyna Jacq., Prunus spinosa L. Picea abies H. Karst
plantations, which were found at a higher altitude, included species such as Vaccinium
myrtillus L., V. vitis-ideae L., Chamaecytisus hirsutus L., Juniperus sibirica Burgsd. The
cover of the shrub layer was 60-70%. The herb layer was well-developed for the Pi-
nus nigra J. ¥. Arnold plantations and had a cover of 50-70%. Some species from the
neighboring habitats such as Poa nemoralis L., Festuca dalmatica (Hack.) K. Richt.,
E heterophylla Lam., Geum urbanum L., Melica uniflora Retz., Fragaria viridis Weston,
etc., were also discovered. Pinus sylvestris L. and Picea abies H. Karst plantations, where
the tree and shrub layers form strong shady effect, had a herb layer with a lower total
cover — 10-40%. The species composition was poorer and the most frequent species
were Luzula luzuloides (Lam.) Dandy & Wilmott, L. sylvatica (Huds.) Gaudin, Poa

nemoralis L., Geum urbanum L.

TI Temperate Salix and Populus riparian forest

Abiotic characteristic: This habitat type was discovered along the riverbeds of Ni-
shava, Glutnitsa, Zli dol and Shumska Rivers at lower altitudes on flat terrains. It cov-
ered an area of 1.8 km’. The alluvial deposits, mainly on carbonate rocks, have been a
prerequisite for the formation of typical averagely deep alluvisols. The habitat type was
presented by 29 polygons. The polygon’s area was in the range of 0.0005—0.63 km’.

Species composition and vegetation structure: [he vegetation had a closed hori-
zontal structure with a total cover of 95—100%. The tree layer (cover about 85-95%)
was dominated by Salix fragilis L. and Alnus glutinosa Gaertn., mixed with Populus
tremula L. and Salix purpurea L. in some sites. The shrub layer had a cover of 40-60%
and was formed by the same species, as the tree layer, but also included Cornus sanguin-
ea L., Prunus spinosa L., Rosa canina L., Rubus caesius L., Sambucus nigra L. The herb
layer was well-developed with a cover of 30-75%. Typical herb species were Aegopo-
dium podagraria L., Agrostis stolonifera L., Urtica dioica L., Lysimachia nummularia L..,
etc. Invasive species, such as R. pseudoacacia L., Amorpha fruticosa L., Erigeron annuus
(L.) Pers. and Conyza canadensis L. were typical as well. This vegetation represents the
habitat type of 91E0*Alluvial forests with Alnus glutinosa and Fraxinus excelsior (Alno-
Padion, Alnion incanae, Salicion albae), included in the Habitat Directive.

TI7 Fagus forest on non-acid soils

Abiotic characteristic: This habitat type had the widest distribution and covered an
area of 51.9 km? in the hypsometric belts between 600 and 1000 m a.s.l and 1000—
1600 m a.s.l. It was common for slightly inclined slopes (up to 20—25°) with various
expositions. It included mainly sedimentary rocks and shallow to moderately deep
Cambisols. It was presented by 211 polygons. The polygon’s area was in the range of
0.0002-7.54 km’.

Species composition and vegetation structure: The horizontal vegetation struc-
ture was closed with a total cover of 90—-100%. ‘The tree layer had a cover of 90-100%.

Forests habitats of Godech Municipality, Western Bulgaria 159

The dominant species was Fagus sylvatica L., accompanied in some stands by Quercus
petraea agg., Carpinus betulus L., Sorbus spp., Tilia spp. The shrub layer included species
from the tree layer as well as Crataegus monogyna Jacq., Corylus avellana L., Chamae-
cytisus hirsutus L., Ligustrum vulgare L., Carpinus orientalis Mill. Its cover was 20-35%.
The herb layer was species-rich with cover 15-65%. The most frequent species were
Aremonia agrimonoides (L.) DC, Mercurialis perennis L., Helleborus odorus ., Polygona-
tum odoratum (Mill.) Druce and some orchid species such as Dactylorhiza cordigera (Fr.)
Soo, Cephalantera longifolia (L.) Fritsch, Neotia nidus-avis (L.) Rich. This vegetation
was classified to class Carpino-Fagetea, order Fagetalia sylvaticae, alliance Cephalanthero-
Fagion. This vegetation represents the habitat type 9150 Medio-European limestone
beech forests of the Cephalanthero-Fagion, according to the Habitat Directive.

T18 Fagus forest on acid soils

Abiotic characteristic: This habitat covered an area of 12.07 km? and was presented
by 2 polygons only, located in Berkovska Mountain in the hypsometric belts between
600 and 1000 ma.s.l and 1000-1600 m a.s.l. The terrains were slightly inclined (up to
15°) and the exposition was variable. Soils were shallow to moderately deep and were
from the Cambisols group. The bedrock consisted mainly of granodiorites, granites,
conglomerates, sandstones, siltstones and limestones.

Species composition and vegetation structure: [he phytocoenoses had a closed
horizontal structure and total cover 90-100%. Fagus sylvatica L. dominated in the tree
layer, which had a cover between 75% and 100%. Other tree species were Acer pseu-
doplatanus L., Quercus petraea agg. and Carpinus betulus L. The shrub layer had a low
cover (10-25%) and was formed from the same species as in the tree layer along with
Rubus hirtus Waldst. & Kit., Corylus avellana L. The herb layer was well-developed
with a cover of 60-80%. There were stands with a cover of only 10%. Species with
higher cover and abundance were Galium odoratum (L.) Scop., Cardamine bulbifera
(L.) Crantz, Mercurialis perennis L., Melica uniflora Retz., Luzula luzuloides (Lam.)
Dandy & Wilmott. This vegetation was classified to class Carpino-Fagetea, order Fag-
etalia sylvaticae, alliance Fagion sylvaticae s.|., associations Asperulo-Fagetum and Festuco
drymejae-Fagetum. ‘This vegetation represents the habitat type 9130 Asperulo-Fagetum
beech forests, according to the Habitat Directive.

TI9 Temperate and submediterranean thermophilous deciduous forest

Abiotic characteristic: This habitat was found on slopes with eastern and southern
exposition mainly in the mountains of Vidlich, Vuchibaba and Ponor mainly in the
hypsometric belts between 600 and 1000 m a.s.l. on slightly inclined slopes (10—15°)
with predominantly eastern and southern components. Soils were shallow to moderately
deep, overlaying mainly carbonates. ‘This habitat type was presented by 212 polygons and
covered an area of 23.70 km’. The polygon’s area was between 0.001 km? and 1.17 km’.

Species composition and vegetation structure: [he vegetation had a semi-open
to closed horizontal structure with a tree layer cover of 75-90%. Quercus cerris L.,

160 Borislav Grigorov et al. / BioRisk 20: 153-163 (2023)

Q. frainetto Ten. and Q. pubescens Willd. were the dominants. They formed mixed
stands with Fraxinus ornus L., Carpinus orientalis Mill., Ulmus minor Mill. and Sorbus
torminalis Crantz. The shrub layer reached 60% cover and included Crataegus mo-
nogyna Jacq., Rosa canina L., Euonymus verrucosus Scopoli, Syringa vulgaris L., Chamae-
cytisus hirsutus L. The herb layer was species-rich with cover in the range of 60-80%,
including many herb and grass species such as Poa nemoralis L., Festuca heterophylla
Lam., Dactylis glomerata L., Galium pseudoaristatum Schur, Aremonia agrimonoides (L.)
DC, Helleborus odorus L., etc. These vegetation types were classified to class Quercetea
pubescenti, order Quercetalia pubescenti-petreae and alliances Quercion confertae and
Quercion petraeo-cerridis. This vegetation represents the habitat 91M0O Pannonian-
Balkanic turkey oak-sessile oak forests and 91H0O *Pannonian woods with Quercus
pubescens, according to the Habitat Directive.

Discussion

Fagus sylvatica L. forests dominate the forest landscape of Godech Municipality with
the two EUNIS types, covering 64.6 km’ in total, following the typical pattern, start-
ed in the Holocene, discussed by Filipovich and Antonov (1996). Fagus sylvatica L.
participated in the last development phase of the forest vegetation in Stara Planina
Mountain. These forests started their expansion 2—3 centuries before the beginning
of the New Era due to climate and, more recently, anthropogenic factors. The forest
belt in Western Stara Planina Mountain, dominated by Carpinus betulus L., once had
a larger territorial extend and the same conclusion can be drawn for the coniferous
species, mainly from the genera of Picea and Abies (Filipovich 1981). Fagus sylvatica’s
timber has been used as a building material for many years. Cleared territories could
experience restoration of Fagus sylvatica L. forests in areas free of weeds, such as Urtica
spp., Pteridium aquilinum (L.) Kuhn., thriving in direct sunlight. This is an example of
interspecies competition. Territories that are more prone to indirect sunlight cannot be
invaded by weeds and Fagus sylvatica L. thrives there (Florov 1952). The restoration of
Fagus sylvatica 1. forests is more difficult on slopes with southern exposition and stony
soils. Forests are restored better at 1000—1300 (1400) m a.s.l. (Garelkov 1973). Ac-
cording to Kumchev (1986) coniferous forests in Stara Planina Mountain will expand
their territories by 2080 from 16 389 ha in 1980 to 26 941 ha. Broadleaved forest will
decrease from 85 144 ha in 1980 to 74 592 ha by 2080.

The forests of Godech Municipality are presented by seven habitat types. They
cover 144.85 km‘ in total, an area divided into 790 polygons, leading to a high rate of
vegetation fragmentation. The habitat type with widest distribution is the T17 Fagus
forest on non-acid soils (51.9 km’), compared to the T3N Coniferous plantation of
site-native trees that dominated the territory of Breznik Municipality (Grigorov et
al. 2022a). Godech Municipality is dominated by beech forests which are typical for
Bulgaria. Despite the fact that the artificial coniferous plantations are not the most
widespread habitat type, they still cover 41.97 km’, taking them into second place.

Forests habitats of Godech Municipality, Western Bulgaria 161

On the opposite side is the habitat type of T1H Broadleaved deciduous plantation of
non-site native trees, which covers only 1.21 km’.

There are several major threats to be addressed. Unfortunately, forest degradation,
destruction and loss due to logging, fires, pollution, pest invasions, erosion etc., are typi-
cal for the study area. Some forest habitat types (T1E, T19) are turning into shrublands,
while others (T11) are experiencing almost total damage. A whole new package of meas-
ures has to be adopted quickly to stop the negative effects, aiming at forest regeneration,
afforestation with native species and ceasing of invasive alien species introduction.

Conclusion

The present study established 7 forest habitat types in Godech Municipality, according to
the EUNIS classification. It represents a continuation of the habitat research of this scien-
tific team in Western Bulgaria. It revealed some of the typical forest problems in Bulgaria
— forest degradation due to natural and anthropogenic factors. The mapping in a 1:5000
scale proved once again to be desirable for analysis making. More research is needed to
reveal the full picture of the forests’ condition in the western parts of Bulgaria. The results
of the current study may be used as a basis for further investigations on this matter.

Acknowledgements

This investigation was carried out with the financial help of the NSP “Young scientists
and postdoctoral students, 2020”, and the National Science Fund (Contract AKOCT
01/7/19.10.2018).

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