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Landscape dynamics of Abies and Fagus in the southern Pyrenees during thelast 2200 years as a result of anthropogenic impacts
Albert Pelachs, Ramon Perez-Obiol, Miquel Ninyerola, Jordi Nadal
PII: S0034-6667(09)00048-7DOI: doi: 10.1016/j.revpalbo.2009.04.005Reference: PALBO 3026
To appear in: Review of Palaeobotany and Palynology
Received date: 26 September 2008Revised date: 24 March 2009Accepted date: 1 April 2009
Please cite this article as: Pelachs, Albert, Perez-Obiol, Ramon, Ninyerola, Miquel,Nadal, Jordi, Landscape dynamics of Abies and Fagus in the southern Pyrenees duringthe last 2200 years as a result of anthropogenic impacts, Review of Palaeobotany andPalynology (2009), doi: 10.1016/j.revpalbo.2009.04.005
This is a PDF file of an unedited manuscript that has been accepted for publication.As a service to our customers we are providing this early version of the manuscript.The manuscript will undergo copyediting, typesetting, and review of the resulting proofbefore it is published in its final form. Please note that during the production processerrors may be discovered which could affect the content, and all legal disclaimers thatapply to the journal pertain.
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LANDSCAPE DYNAMICS OF ABIES AND FAGUS IN THE SOUTHERN
PYRENEES DURING THE LAST 2200 YEARS AS A RESULT OF
ANTHROPOGENIC IMPACTS
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Albert Pèlachs a,*, Ramon Pérez-Obiol b, Miquel Ninyerola b, Jordi Nadal a a GRAMP, Departament de Geografia, Universitat Autònoma de Barcelona. 08193 Bellaterra (Cerdanyola del Vallès). Spain. b Unitat de Botànica, Facultat de Biociències, Universitat Autònoma de Barcelona, 08193 Bellaterra (Cerdanyola del Vallès). Spain. * corresponding author. Tel.: +34 93 5868057; fax: +34 93 5812001. E-mail address: [email protected] (A. Pèlachs).
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LANDSCAPE DYNAMICS OF ABIES AND FAGUS IN THE SOUTHERN
PYRENEES DURING THE LAST 2200 YEARS AS A RESULT OF
ANTHROPOGENIC IMPACTS
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Abstract
The vegetation landscape dynamic is derived from the relationship established between
a society and its environment through time, and the current landscape has never been
seen in the previous 2000 years. The pollen study of a core from a peat bog in València
d'Àneu (Lleida, NE Iberian Peninsula) shows a maximum extension of Abies alba forest
about 2200-2000 cal. yr BP. Later on, there is evidence of selective actions affecting
this forest and the expansion of Fagus sylvatica at about 2000-1300 cal. yr BP.
Beginning in 1300 cal. yr BP, deforestation due to agricultural activities expanded and
beech definitively disappeared at 800 cal. yr BP. Natural and human disturbances
affected the dynamics of Abies alba and Fagus sylvatica from their first appearance to
the current vegetation landscape. Human impact on the silver fir forest, which reached
its maximum in the last millennium, favoured the beech population. Pollen data from
this region support our finding that human impact, not climate, is the most important
influential factor in the development of beech forests.
Keywords: Pyrenees, Holocene, palynology, GIS suitability mapping, Abies alba,
Fagus sylvatica.
Introduction (A)
The current discussion concerning the dynamics of the vegetation landscape is rooted in
the reasons for change over time and in the weighting of natural and human factors in
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its evolution (Galop and Jalut, 1994; Esteban et al., 2003; Riera et al., 2004; Beaulieu et
al., 2005; Riera et al., 2006; Pèlachs et al., 2007). Although climatic factors have a very
important role in the development of vegetation, palaeobotanic studies have
demonstrated the importance of taking into account the role played by human society.
Therefore, the primary objective of this study is to determine the extent to which the
human imprint has affected the current vegetation landscape, focussing on the dynamics
of Abies and Fagus forests in the Pyrenees.
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Colonization of Abies alba and Fagus sylvatica: the current state of affairs (B)
An explanation of the plant colonization of the Pyrenees from the beginning of the
Holocene can be undertaken on the basis of pollen analyses available from the Pyrenees
mountain range (Jalut et al., 1998). It is impossible to interpret which factors affect this
evolution without taking into account at least three variables: the location of refuge
zones, the development of climatic factors and the edaphic dynamics of the soils
(Pèlachs, 2005).
In recent years, the study of Abies alba dynamics in Europe (Terhürne-Berson et al.,
2004; Liepelt et al., 2009) has been associated with other species, such as Fagus
sylvatica (Tinner and Lotter, 2006). This area of study has developed from a series of
interpretations based on the study of climate change, migratory change, unequal growth
of species, and the effects of human disturbances and forest fires (Tinner and Lotter,
2006).
In this sense, phylogenetic studies reveal how the Abies populations in the Pyrenees
were isolated from the rest of Europe (Konnert and Bergmann, 1995). This argument
was definitive in defending the proximity of the Pyrenees to Abies alba refuge zones,
based on plant macroremains and pollen data (Terhürne-Berson et al., 2004; Liepelt et
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al., 2009). The hypotheses about distribution from the glacial refuges based on
isoenzyme studies and other genetic markers (El Mousadik and Petit, 1996) seem to
substantiate the existence of five areas of Abies alba refuge and recolonization: the
Pyrenees, central and eastern France, central Italy and the southern Balkans. Pollen and
genetic data indicate clearly that the Abies alba and Fagus sylvatica refuges in the
Pyrenees have suffered the “bottleneck” phenomenon during their history and that
recolonization was not produced exclusively from refuge populations. This theory is
well supported because of the low allelic levels, which can be correlated to the current
distribution of silver fir in the Pyrenees, with populations that are not extensive in
comparison with the rest of Europe.
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Palaeobotanical and genetic data for Fagus sylvatica (Magri et al., 2006) have been
used to evaluate the genetic consequences in Europe of long-term survival in refuge
areas and postglacial spread. The largely complementary palaeobotanical and genetic
data indicate that Fagus sylvatica survived the last glacial period in multiple refuge
areas. The central European refuges were separated from the Mediterranean refuges,
which did not contribute to the colonization of central and northern Europe. Likewise,
some populations expanded considerably during the postglacial period (Magri, 2008),
while others experienced only limited expansion. According to Ninyerola et al. (2007a),
inferences from more than a few studies lend credibility to the presence in the
Mediterranean of deciduous taxa such as Fagus during the early and mid-Holocene. The
climatic suitability of Fagus during the early Holocene has been shown by Lozano et al.
(2002), who identified Fagus and dated it at c. 17,895 cal. yr BP in Urdaibai (Basque
County) or López-Merino et al. (2008) in Sierra de Neila at c. 15,600-13,700 cal. yr BP.
This led them to suggest the northern Iberian Peninsula as a possible refuge zone
(Hewitt, 1999). In the Balearic Islands, the available data (Ninyerola et al., 2007a;
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Pérez-Obiol and Sadori, 2007) seem to indicate that Fagus had refuge in some concave
areas during the upper Pleistocene and the Holocene. The presence of small stands of
Fagus in Majorca, before the colonization from the Pyrenees took place, makes this a
credible hypothesis. Similarly, examining the Iberian Peninsula, Pott (2000) indicates
that over the last 9000 years Fagus has colonized northern areas from diverse
Pleistocene Mediterranean refuges.
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In the Iberian Peninsula, evidence exists (Costa et al., 1998) of the presence of Fagus
sylvatica in the Basque Country (Saldropo) and Tramacastilla more than 4000 and 7000
years ago, respectively, which would confirm the presence of various refuge zones in
the southern slope of the Pyrenees (Montserrat, 1992). This pattern of colonization is
supported by pollen records from the northeast Iberian Peninsula (Pérez-Obiol, 1988),
showing that Fagus colonization began between 8800 and 7850 cal. yr BP.
The difficulty comes from site differences that enormously complicate the interpretation
of local pollen and charcoal records, as at Burg Lake in the Pyrenees, close to the study
area, where Fagus sylvatica does not appear until 3000 cal. yr BP (1050 BC) (Pèlachs,
2005).
On the other hand, regional data support the introduction of Fagus sylvatica at Redó
Lake at about 4900 cal. yr BP (Catalan et al., 2001), and a little later at Redon Lake
(Catalan and Pla, 1998), where it arrives in about 4500 cal. yr BP, probably as a
consequence of the difference in altitude (Esteban et al., 2003). Miras et al. (2007)
implicate both anthropic participation and onset of new climate conditions (lower
summer temperatures and higher annual precipitation) in the timing of the first regular
observations of Fagus sylvatica in the Andorran valley of Madriu, at about 4800 cal. yr
BP.
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Similarly, much farther west of the Pyrenees, Montserrat (1992) explains that, although
beech appears intermittently at Ibon de Tramacastilla after 7859 cal. yr BP, its curve
does not become continuous until c. 5760 – 4476 cal. yr BP, making its appearance
contemporaneous with the other Pyrenees sites.
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No one disputes that the Abies alba dynamics in the Pyrenees during the Holocene
indicate colonization followed by expansion from east to west (Jalut et al., 1998;
Esteban et al., 2003; Pèlachs, 2005; Le Flao, 2005), which would confirm the existence
of refuges located in the Mediterranean basin. In fact, analysis of the current western
boundaries of Abies alba in the Pyrenees shows a progressive lag between the western
and eastern half of the mountain chain, which could be attributed to the progressive
distancing of this conifer from its refuge areas (Reille and Andrieu, 1991). Similarly,
some authors have reported that this species first developed on the north slope of the
Mediterranean Pyrenees at 11,224 cal. yr BP, specifically in the area of Nohèdes (Jalut,
1974; Reille and Lowe, 1993); this is consistent with the very first appearance of Abies
alba in the Garrotxa at about 10,204 cal. yr BP (Pérez-Obiol, 1988). Other registries of
long-term silver fir presence in the eastern Mediterranean also concur, e.g., Pla de
l’Estany (Burjachs, 1994), Banyoles (Pérez-Obiol and Julià, 1994), and Abric Romaní
(Burjachs and Julià, 1994), confirming the presence of refuges in coastal zones and in
intramountain valleys of the Iberian Peninsula (Carrión-García et al., 2000). Therefore,
colonization of Abies alba and Fagus sylvatica in the meridional slope of the Pyrenees
could be due, in part, to refuge zones located to the south and east of the Pyrenees (Fig.
1).
[FIGURE 1]
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Present day distribution of Fagus and Abies in the Iberian Peninsula related to
anthropogenically forced landscape changes (B)
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Although climate has been regarded as the determining factor in the development of
Fagus sylvatica forests at c. 4500 cal. yr BP (Jalut, 1974; Giesecke et al., 2007), it has
also been demonstrated that human influence may be responsible for its strong
expansion at that time (Kenla and Jalut 1979; Jalut 1984; López-Merino et al., 2008).
According to Tinner and Lotter (2006), beech survived human pressure, while other
deciduous trees (e.g. Tilia, Ulmus, Fraxinus excelsior) and silver fir (Abies alba) were
strongly disadvantaged. The authors hypothesize that in the absence of human impact,
silver fir would have expanded to areas in Europe where the species is absent today.
According to Peñalba (1994), the western and southernmost parts of the peninsula have
not been colonized by Fagus. The absence of Fagus in northwestern Spain is striking,
given the importance of this genus in similar climatic conditions in the other Cantabrian
regions. It is unlikely that the spread of Fagus was stopped in Galicia by natural causes
at 1390 cal. yr BP. At that time, humans exerted strong influence on the vegetation in
this region; their presence there is recorded since 5760 cal. yr BP. Anthropogenic
disturbance has proved responsible for the final, abrupt decline of Fagus populations in
the Cantabrian region. It is likely that severe anthropic pressure on populations of Fagus
at their range limit stopped the spread to the west. A similar situation could be inferred
for Abies, confined today to the eastern part of the Pyrenees although it had a wider
distribution in the Iberian Peninsula during previous interglacial periods. Two facts
must be considered: first, man favoured Fagus to the detriment of Abies at the
beginning of its extension to the northern side of the Pyrenees (Jalut 1984), and second,
Abies grows today in Italy under climatic conditions also found in Spain (Terhürne-
Berson et al., 2004; Liepelt et al., 2009), suggesting that the spread of the species into
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the Iberian Peninsula could have been stopped by human interference in the Pyrenees.
Nevertheless, climate forcing in the Post-Bronze Iberian Roman Humid Period (2600-
1600 cal. yr BP) could be a consideration, as proposed by Martín-Puertas et al. (2008).
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Fig. 2 shows the clear decline of Abies alba beginning in the medieval period. When the
human impact was too strong, silver fir totally disappeared (Pérez and Roure, 1990;
Pèlachs, 2005; Tantinyà, 2007).
The potential distribution of Abies alba in the northwest Iberian Peninsula proposed by
Rivas (1987) would result in a much larger region with a much more suitable surface if
we consider numerous biotic and abiotic factors that exist at present. To enhance the
potential distribution of these two taxa, a combined spatial suitability surface has been
developed through GIS and multivariate statistical methods. This map allows us to
understand the spatial behaviour of Fagus and Abies at regional scale, complementing
the palaeopalynological results.
[FIGURE 2]
Study Area (A)
The Prats de Vila peat bog (longitude 1° 6’ 13” E and latitude 42° 38’ 17” N) is found at
1,150 masl and has an estimated area of 2.8 hectares. The lithological substrate
corresponds to Cambro-Ordovician slates, even though during the fieldwork we found
important granite deposits of glacial remains.
The climatic conditions surrounding the peat bog (within a 1 km radius) are humid
(Thornthwaite humidity index) with an Autumn-Spring-Summer-Winter precipitation
pattern and mean annual values ranging between 652 mm and 887 mm (=736 mm). The
mean annual temperature ranges between 6.5 ºC and 10.5 ºC (=8.9 ºC), decreasing in
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winter to a mean minimum temperature of around -3.8 ºC. Potential evapotranspiration
(computed following the Hargreaves method) shows annual values ranging between 574
mm and 850 mm (=716). These values are close to precipitation values, meaning that
this area is free of hydric stress. All the climate data have been extracted from the
Digital Climatic Atlas of the Iberian Peninsula (Ninyerola et al., 2007b and 2007c).
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The present vegetation on the peat bog is Subalpine-Montane mesophilous and siliceous
meadows with Agrostis capillaris, Festuca nigrescens, Anthoxanthum odoratum,
Galium verum, and Genistella sagittalis. Vegetation surrounding the peat bog in shady
places includes some deciduous Quercus together with Corylus, Betula and Pinus,
which in many cases occupy formerly cultivated fields and give way to the most
extensive Abies alba stands of the Pyrenees: la Mata de València d’Àneu. In northern
Spain, distribution of Quercus petraea (the dominant oak near the study zone) is
typically fragmented. Taking into account its minimal presence in the pollen diagram, it
appears that its distribution area in the study zone has not been of great importance
during the last millennia. At the same time, in sunny places, the deciduous Quercus
share their protagonism with Q. Ilex subsp rotundifolia.
Materials and Methods (A)
The study methodology was based on a combination of pollen data extracted from a
peat bog in València d’Àneu (Axial Pyrenees) and fieldwork to identify the main plant
communities in the zone.
Three core samples were taken with a mechanical sampler and the one with the most
consolidated peat was selected for analysis. Two large, clearly differentiated
sedimentary units have been described in the register of the peat bog studied (Fig. 3):
the upper unit, characterized by the abundance and continuity of the bog, and the lower
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level, characterized by a granite conglomerate with very compacted gravel and some
pebbles at the transition between the two units. Two samples were selected for dating
using
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14C-AMS (Beta Analytic Inc.), based on a piece of wood at 59-60 cm depth and a
peat fragment at 165-166 cm depth (Table 1). The resulting sedimentation rate for the
peat section was 0.72 mm/year for the first 60 cm and 0.83 mm/year for the rest. Age
was calibrated to calendar age using the INTCAL04 program (Talma and Vogel, 1993).
For the pollen analysis, we selected only the first two meters of peat from one of the
cores (named VAL-III), down to the transition to gravel conglomerate. Chemical
treatment of the samples was carried out according to the protocol described by Goeury
and Beaulieu (1979).
[FIGURE 3]
[TABLE 1]
Suitability mapping (B)
The suitability vegetation maps for Fagus and Abies were developed using presence-
absence models adjusted with logistic linking in a General Linear Model (GLM).
Presence data were obtained by choosing plots where these species are dominant from
the third National Forest Inventory (a project administered by the Spanish state). The
resulting distribution of both species is shown in figures 7-8. This forest inventory
regularly samples the territory with a grid density of 1 km. This type of sampling is
very interesting because it covers a large area but especially because regular sampling
avoids the sampling bias that exists in many other types of chorological data. We would
also note that we have access to plots in which the absence of the species studied is
ensured, mitigating the problem of pseudo-absences (Chefaoui and Lobo, 2008). To
obtain an absence sample, we randomly chose a number of sites equal to the presence
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sites. In addition, plots that were absence sites for the species we considered were
avoided if they were within a 5 km radius of the presence plots and therefore had very
similar topoclimatic conditions.
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With respect to predictor variables, we incorporated geoclimatic variables obtained by
spatial interpolation methods (Ninyerola et al., 2000), based on a Digital Elevation
Model with 200-m resolution and data from Spain’s National Institute of Meteorology
(INM), which provided readings from 1346 temperature stations and 2519 for
precipitation. We would emphasize here that having access to a plot that was
georeferenced with a high level of precision allowed us to capture the climatology at
toposcale, minimizing methodological errors. Five variables were analysed: maximum
mean temperature for the warmest month, mean annual temperature, minimum mean
temperature for the coldest month, accumulated precipitation by season and potential
solar radiation by season. Table 2 shows the ranges for Abies alba and Fagus sylvatica.
We then enriched the databases using vector point files (presence-absence distribution)
with the corresponding values from the geoclimatic variables. This enriched database
was submitted to statistical analysis using a GLM with logistic linking, as in other
studies (Felicísimo et al., 2002) of the suitability of forest species. For the process of
adjusting the model we used 60% of the plots and saved 40% for validation and to be
able to quantify in this way the quality of the resulting maps.
Finally, mapping algebra was used to obtain the suitability maps by species using the
completed analysis. The regression equations, adjusted by statistical analysis, were
reproduced using GIS, replacing each variable with the corresponding topoclimatic
map.
[TABLE 2]
Results and discussion (A)
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Pollen diagram from the València d’Àneu peat bog (B) 264
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The pollen diagram from the València d’Àneu peat bog permitted us to reconstruct the
vegetation changes in the studied zone over the last two millennia (Fig. 4). The diagram
is described using pollen assemblage zones (PAZ).
[FIGURE 4]
VAL-III / I (2200-2000 cal. yr BP; 250 BC –50 BC): the decline of the
“original”Abies alba forest (C)
At the beginning of this time period, Abies frequency of more than 10% with a peak at
approximately 22% can only be explained by the Abies alba in situ occupying a much
larger land area than at present. The drop in Abies at the end of this period may be due
to selective human intervention with respect to this species, favouring other species
such as Corylus, which would colonize the space left by silver fir. We must take into
account the fact that wood forms part of the Roman social and economic system and is
an indispensable element (Conedera et al., 2004).
Mining is another sector related to exploitation of forest resources. We noted an
increase in lead in the sediment of Redon Lake (also in the axial Pyrenees) during the
Roman era and a high point in about AD 600 (Catalan and Pla, 1998). The dating of five
charcoal kiln sites between the 3rd and 4th VI centuries AD and the identification of
charcoals (Pinus and Abies) allows us to relate this first metallurgy with selective acts
related to the forest (Pèlachs and Soriano, 2003).
VAL-III / II (2000-1300 cal. yr BP; 50 BC – AD 650): Abies alba forest with Fagus
sylvatica (C)
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The intervention of the prior phase on the Abies alba forest opens up land that is
occupied first by some species that are typical of meadows and clearings (Poaceae,
Plantago sp., Asteraceae, etc.) and permit the expansion of plant populations that
compete with the silver fir for space, such as Corylus in the lowest areas and Fagus,
Pinus and Betula in the same zones as the Abies alba.
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The occasional presence of Juglans, Juniperus and Artemisia and the start of Cerealia
and Castanea curves denote human management of the landscape, mostly related to
grazing and agricultural activities. Pseudoschizaea (an algal remain indicative of
erosive processes) appears. The first occurrences of Juglans are well dated at Ariege
(2000±107 cal. yr BP in Jalut el al. 1982; 1792±59 cal. yr BP, Galop, unpublished).
There are regular records from the 10th to the 13th centuries, though the dates may vary
with area and altitude (1048±79 cal. yr BP and 706±28 cal. yr BP, Galop, unpublished;
near 643±61 cal. yr BP, Planchais 1985). This cultivated tree is an excellent marker of
the Greco-Roman times. It was introduced in western Mediterranean regions as early as
c. 1952 cal. yr BP (Bottema, 1980) by Greek and Roman settlers. According to the
curve of pollen concentration (pollen grains/g), the arboreal biomass does not suffer a
significant decline (Fig. 5). However, forest activities are evident.
In any case, the plant dynamics indicate a human pressure that shifts the permanent
character of the land. Without technical resources to minimize labour expenditure, mid-
slope soils are preferred for agricultural uses (Esteban et al., 2003). This is the reason
for disturbances of mid and lower slopes of the forest that affect the dynamics of the
silver fir-beech forest.
[FIGURE 5]
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VAL-III / III (1300-650 cal. yr BP; AD 650 – AD 1300): the explosion of human
activities (C)
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This entire phase is characterized by a declining AP percentage and an absolute increase
of herbaceous plants (Fig. 5). The massive forest clearance during this period is shown
by the fall in AP values and the greater Poaceae abundance in the studied area. The
decline of Abies and the noticeable extension of Fagus are probable evidence of this
deforestation.
The pollen diagram shows certain peculiarities that led to splitting the zone into three
subzones:
VAL-III / IIIa (1300-1100 cal. yr BP; AD 650 – AD 850): global disturbance (C)
At the same time that Pinus recedes below 20% and Abies falls below 5%, Fagus,
Betula and Corylus take advantage of this by increasing their presence even though,
later on, they will decline just as the rest of the tree population did.
The large increase in Artemisia, Poaceae, Rumex and Polygonum can be explained by
the increase in grazing. The strong increment of Cerealia (mostly Secale) and Fabaceae
also indicate the implementation of agricultural practices. This evidence permits us to
assume that opening up the landscape led to the arrival of Olea pollen. In that era, olive
tree cultivation is documented in the domains of a nearby monastery (Esteban et al.,
2003). These facts are clearly evidenced by the drop in pollen concentration. The impact
of human disturbance is more noticeable from the Late Medieval period onward.
VAL-III / IIIb (1100-800 cal. yr BP; AD 850 – AD 1150): management of the peat
bog (C)
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This zone is characterized by the notable presence of Alnus, which together with the
dynamics of Cyperaceae and Typha-Sparganium pollen type allows us to connect this
period with an increase in the groundwater level of the peat bog and possibly with its
expansion.
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Sparganium sp. has great colonizing abilities and may cause a rapid silting in shallow
waters. At this time, its development coincides with the establishment of Alnus. Before
this colonization, Pediastrum was already present, indicating a rise in water level. These
percentage increases in taxa are related to a major sedimentary stability (Andrieu et al.,
2000). Late Medieval period documents explain that during this period it was common
to plant crops in muddy zones along river banks, which flooded periodically and were
called “insules” (Esteban et al., 2003); consequently, it would seem reasonable that a
hygrophilous environment was favoured, controlling the flow and the hydric resources
of the area.
The rapidly invading Abies would out-compete Fagus, or substantially slow down its
recruitment rate until canopy disturbance created light openings large enough for
successful establishment and growth. According to Doležal et al. (2004), the higher
mortality of Fagus in denser Abies patches and the resulting spatial segregation of the
species reflect asymmetric interspecies competition.
VAL-III / IIIc (800-650 cal. yr BP; AD 1150 – AD 1300): disappearance of the Abies
alba-Fagus sylvatica forest (C)
The beginning of this phase is characterized by high percentages of Poaceae and
Cerealia and the disappearance of Fagus from the study area, a disappearance attributed
to the strong human impact on the landscape. From this point on, there will never again
be a beech forest or a small mixed Abies alba-Fagus sylvatica forest in the zone. This
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drastic change in the forest landscape is also evidenced by the decline in Alnus, Abies
and Pinus, which at the end of the sequence permits the return of Corylus.
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VAL-III / IV (650-350 cal. yr BP; AD 1300 – AD 1600): recovery of the Abies alba
forest (C)
Since 650 cal. yr BP (AD 1300) we have observed a certain recovery of the arboreal
cover, led by the presence of three primary species of trees that are distributed and
combined in various stages and habitats: Corylus, Abies and Pinus; Betula is added to
the list at the end of this time period. Human pressure on the environment is moderate.
Therefore, it doesn’t seem that the repercussions of the Little Ice Age were sufficiently
important to affect the economic activities of the dominant classes, primarily herders.
All the same, documents report major declines in the Pyrenees in some of the species
grown (such as grapevines), which leads us to assume the existence of local differences.
VAL-III / V (350-150 cal. yr BP; AD 1600 – AD 1800): a new increase in human
pressure (C)
The slight percentage oscillations in various tree taxa, such as Abies, Corylus, Betula
and Pinus, are accompanied by a large increase in Poaceae and Juglans; this denotes a
new and different landscape management with the existence of pastures and plantations
of trees. It is worth noting that oil was extracted from the walnut trees and had a high
food and therapeutic value, equal or superior to that of olive oil, and therefore at
particular times could have offered an alternative to the cultivation of olive trees
(Esteban et al., 2003). In addition, the appearance of Ericaceae could indicate an
increase in ruderal species, given the use of a road network, and that of Glomus would
explain the more edaphic conditions of the peat bog.
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VAL-III / VI (150 cal. yr BP--present; AD 1800 – present): the preamble to the
current landscape (C)
The final episode puts the vegetation landscape at the doorstep of the current landscape,
with the percentages of Abies at about 5%, while Pinus recedes significantly and
heliophilous colonizers increase progressively in formerly cultivated zones and open
forest areas, including Corylus –especially at the end of the sequence – or plastic
species such as Betula. This occurred in other areas as well.
This denotes a decrease in the groundwater of the peat bog as indicated by the curve for
Cyperaceae and Glomus and suggests the definitive disappearance of Alnus around the
bog studied here. Chlamydospores of Glomus cf. fasciculatum would be evidence of
erosive phenomena (Van Geel et al., 1989) related to anthropogenic activity and drought
(López-Sáez et al., 2000).
[FIGURE 5]
Vegetation dynamics and suitability (B)
It is clear from the palynological data presented here that human impact became
stronger and reaches its maximum in this last millennium. This stage of the Pyrenean
forest history saw the final shaping of the present-day landscape (Kenla and Jalut 1979;
Galop, 1998).
The pollen diagram is comparable to numerous diagrams of the southern and central
Alps, central France and the Pyrenees themselves (Beaulieu, 1978; Clerc, 1988; David,
1993; Nakagawa, 1998; Tinner et al., 2005; Finsinger and Tinner, 2006; Pèlachs et al.,
2007). In the central Alps, Nakagawa et al. (2000) found a sequence that is
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chronologically similar and has three stages of impact, each of which is followed by a
different pattern of forest restoration. The first deforestation occurs at about 2060 cal. yr
BP, during the Roman era, and a selective exploitation of Abies alba forest is evidenced.
The silver fir forests formed part of a very active economy near the Rhine river. Küster
(1994) compiles various pollen diagrams for the Rhine, Elbe, and Danube and
demonstrates that the use during Roman times was not totally destructive. Various
zones of silver fir forest were left untouched. The author concludes that the concept and
practice of “forest management” was common in Roman times. The second
deforestation, around 1520 cal. yr BP (or during the 5
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th and 6th centuries), denotes
substantial evidence of agricultural activity. The third, around 810 cal. yr BP or right in
the middle of the 12th century, is similar to its predecessor but much longer and not at
all selective, so that the forest had no chance to recover.
These facts coincide quite well with the changes in percentages and pollen
concentration for Abies (Fig. 5). This dynamic also coincides with those found in other
localities close to the studied zone (Esteban et al., 2003; Pèlachs et al., 2007). The peat
bog studied demonstrates much more clearly a possible selective action involving Abies
alba forests during the Roman era and confirms the indices that explain how some
dynamics began in the medieval period, continued during the Modern Age and the 20th
century, and brought us to the current landscape.
In other areas of the Pyrenees, Abies alba was the primary species of trees between
6200 and 2800 cal. yr BP (4250-850 BC), a time when the stable Abies alba presence
gave way to red pine forest in the subalpine stage. At the same time this was happening,
a mixture of oak (Quercus sp., Tilia sp., Ulmus sp. etc.) also experienced a sharp
decrease. This strong disturbance of the subalpine and mountain area would permit the
pine forest to expand as a rapid colonizer and populate the space that had been occupied
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by silver fir; this was the product of accumulating circumstances where climate change
and human actions intersected (Pèlachs et al., 2007). In the studied zone this didn’t
happen and the silver fir, despite the strong disturbance they suffered, recovered again
and again, even though the population would never reach the levels of 2000 years
earlier (Fig. 4). Abies forests remained important during a large part of the Holocene,
which could be explained by the topography of the valley and slopes.
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The current pollen spectrum had never been seen in the previous 2000 years. This fact
led us to deduce that models such as Modern Analogue Technique (MAT) could be
difficult to apply in this zone of the Pyrenees, at least during the last 2000 years.
Establishing detailed comparisons, we observe notable differences between two data
groups of interest: pollen and vegetation cover; this means that we must explore models
that work for mountain regions in particular. Calibrating the mountain vegetation and
pollen spectra is key to this type of research if we are to understand certain evolutionary
patterns. The hypotheses of authors such as Muller et al. (2005), which postulate that
there is an increase in regional and distant pollen in sediment at high altitude, is only
valid for certain taxa. In sedimentary samples of lake surfaces, we see that the presence
in the pollen spectra of taxa such as Tilia, Abies, Ulmus and Fagus almost always
represents a local or nearby presence in mountain regions. Many calibrations have used
correction factors or R-values (the ratio between the pollen group and the vegetation
community it represents). At present, different models are grouped within the Extended
R-value (ERV). With respect to Abies, a taxon that has had a strong impact on the
evolution of the vegetation landscape in this zone during the last 2000 years, it must be
said that it is very sensitive to the described method of weighing distance. For example,
according to Eisenhut (1961) Abies alba presents a falling speed of 0.12m.s-1, while
other similar plants such as Pinus sylvestris have values of 0.056 m.s-1. We must always
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think in terms of intertaxonomic differences if we are able to properly interpret pollen
dispersal and deposition patterns.
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The pollen analysis presented advocates the possibility of an anthropogenic trigger for
Fagus sylvatica expansion. Many other studies suggest that human disturbance
facilitated the expansion of this tree where climatic conditions were favourable (Küster,
1997). This hypothesis has its origin in northern and north-western Europe (e.g.
Andersen, 1973; Iversen, 1973), where Fagus sylvatica expanded only after the
beginning of the Neolithic (Lang, 1994). According to Tinner and Lotter (2006: 541):
“human activities as one (if not the most important) cause for the invasion of Fagus
sylvatica into Central Europe (e.g., Küster, 1997, 1999; Ralska-Jasiewiczowa et al.,
2003) has repeatedly been questioned and is still debated (e.g., Huntley et al., 1989;
Lang, 1994; Huntley, 1996; Gardner and Willis, 1999; Pott, 2000)”. In locations where
Fagus is found forming monospecific communities, it is because in the middle of its
distribution area young beech has behaved like an eurioic species with a broad
ecological valence, capable of shaping itself to edaphic and climatic conditions that are
relatively diverse (Costa et al., 1998), which gives a certain advantage in confronting
Abies alba and other colonizers. From this point on it seems logical to think that Fagus
sylvatica was occupying the lower part of the Abies alba forest, exactly in the place that
was cut and burned to convert the land to cultivated fields. For this reason it did not
repopulate and was replaced by hazelnut. This process could only begin in the Middle
Ages, with the availability of technologies to occupy the valley floor, the experience
necessary to manage the drainage of peat bogs, and the consolidation of fluvial
boundaries, in addition to the political capacity to carry out the appropriation of these
spaces. In this moment in the history of “slash and burn” agriculture, which means that
itinerant agriculture was replaced by the permanent roturation of valley floors, a fact
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that required limiting the diversity of resources available to peasants, who had to
specialize in specific products selected not for their productivity but rather for their
adaptability to feudal uses (Esteban et al., 2003).
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According to the ecological literature, Tinner and Lotter (2006) affirm that Fagus
sylvatica and Abies alba have similar environmental requirements. These authors have
put on record that 1) today, Abies alba is more competitive than Fagus sylvatica where
summer precipitation is higher and temperature is lower (Ellenberg, 1996) and 2)
palaeobotanical evidence suggests that high summer precipitation is more important for
Abies alba than low temperatures. If we analyse the distribution of Abies alba in the
Spanish National Forest Inventory, we see how the silver fir on the Iberian Peninsula
today live with a mean annual precipitation of about 1100 mm/year and an estimated
mean annual temperature between 3.5ºC and 10.5ºC (Ninyerola, 2001). In the Iberian
Peninsula, young beech stands are found in zones in which the monthly average
temperatures fluctuate very little between the coldest and warmest month. Normally this
change does not exceed 15 ºC, although it might reach 25 ºC in the middle of the
peninsula. Young beech has great resistance to cold during the fallow times.
The present-day suitability maps of Abies, Fagus and Abies-Fagus mixed forest can be
observed in Fig. 6 and Fig. 7. If we focus on the area closest to the studied peat bog, we
find low (<0.3) and intermediate (0.3-0.7) Fagus suitability values. The closest nucleus
with high suitability (>0.7) is found about 10 km east of the bog. In contrast, with
respect to Abies we can see that cells with intermediate values dominate and, most of
all, less than 2 km away we find abundant areas that are highly appropriate for this
species. This makes one think that the studied area, and nearby zones, have topoclimatic
characteristics that are more favourable to the development of Abies. This situation is in
accord with the interpretation of the pollen diagram (Fig. 5), which makes us think that
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Abies recovers more readily when topoclimatic factors outweigh anthropic ones. From
the point of view of plant suitability, we can consider the València d’Àneu peat bog as
located in an area where the influence of ideal zones for Abies is clearly higher than for
Fagus. Statistical details of the model (adjustment and validation) underlying this
cartography can be found in table 3.
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[FIGURE 6]
[FIGURE 7]
[TABLE 3]
5. Conclusions (A)
The València d’Àneu peat bog has been shown to be a good palaeoenvironmental
record, giving us an image of the short-term changes that make possible a study of the
abrupt anthropic effects. The pollen analysis has made evident, in no uncertain terms, a
possible selective action affecting Abies alba forest in the Roman period and confirmed
the indicators that explain how during the medieval period some dynamics began that
would evolve during the Modern Age and the 20th century to produce the current
landscape in this area. The current vegetation landscape of this region of the Pyrenees
has never before existed over the course of the last 2000 years and the climatic frame is
not well represented due to human disturbance of the landscape during this period.
The surroundings of the peat bog provided good conditions for human settlement and
pastures by removing forest. The palynological data support that human impact became
stronger and reached its maximum in the last millennium.
A direct climatic inference cannot be made. It is not possible to isolate the human
presence from the plant dynamics and therefore there can be no clear correlation during
this period between climate and original vegetation.
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Silver fir shows a decline in this area due to factors much more related to human
intervention than to climate. Likewise, Abies recovers with a certain ease, in contrast to
what happens in other parts of the Pyrenees and pre-Pyrenees; a higher suitability with
respect to its current habitat is evidenced.
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During the first millennium of our era, we note the presence of beech woods, most
likely coexisting with Abies alba as a product of continual and selective actions in the
forest. Fagus sylvatica acts as a colonizer of open space and can be? directly related
with human activity, especially since the Middle Ages, provoking a change in the
altitude limits of forest and other ecotonic zones. In the same way, the maximum levels
of Corylus avellana currently present are due to the colonization of humid lowlands
previously used for crops and pasture.
In summary, then, plant succession over the past two millennia in the studied area can
be described as a maximum extension of Abies alba forest (2200-2000 cal. yr BP);
selective actions affecting the silver fir forest and arrival of beech (2000-1300 cal. yr
BP); deforestation as the agricultural zone expanded, with a reduction in the upper
altitude limit of the forest and definitive disappearance of Fagus sylvatica (1300-800
cal. yr BP); total Abies alba deforestation (800-650 cal. yr BP) and the recovery of
silver fir forest (without Fagus sylvatica presence) that, with various fluctuations,
persists into the present.
Acknowledgments (A)
This research would not have been possible without the support received from those
responsible for the High Pyrenees Natural Park; we especially want to acknowledge
Agustí Esteban Amat for his sensitivity to environmental research and his knowledge of
the area. Sampling of the peat bog was possible thanks to the efforts of Aureli Carnicer
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and also of COPCISA, which authorized access under the supervision of María Álvarez,
to whom we are especially grateful for the assistance she provided. We also wish to
gratefully acknowledge the unselfish collaboration in the field that we received from
Riker Yll and Jordi Llorens. Finally, the authors thank Elaine Lilly, Ph.D., of Writer’s
First Aid for English translation and revision.
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Fig. 1. Location of the València d’Àneu (VAL-III) peatbog (star) and fir forest (in grey)
in the Pyrenees.
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Fig. 2. Current distribution of Abies alba (white dots) in the Pyrenees and first
occurrences and dynamics during the Holocene (Pérez-Obiol, 1988; Pèlachs et al.,
2007).
Fig. 3. Lithologic column and sediment structure of the peat bog.
Fig. 4. Main taxa pollen diagram and calibrated dates from the València d’Àneu (VAL-
III).
Fig. 5.
Left: Non Arboreal Pollen Concentration vs. Arboreal Pollen Concentration (pol/g).
Right: Arboreal Pollen Concentration of Abies alba and Fagus sylvatica. Peat bog of
València d’Àneu (VAL-III)
Fig. 6. Suitability maps of Abies alba (a) and Fagus sylvatica (b). Dots represent the
present observed distribution (National Forest Inventory). High, medium and low
suitability are denoted by black, grey and white tones, respectively.
Fig. 7. Suitability map of mixed Abies-Fagus. This map is based on the layered
combination of suitability maps of each species. Black colours represent areas where
both species have high suitability, grey tones where only one has high suitability and
white colour where there is no suitability.
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819 Fig 1
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833
Sample (cm)
Laboratory Code
Material Conventional dating BP
Dating calibrated to 2σ (95%
probability)
Intercept calibration curve
59-60 Beta-240388
Wood 780±40 cal BP (730-680) cal BP 690
165-166
Beta-240387
Peat 1990±50 cal BP (1990-1880) cal BP 1940
834 835 Table 1. 14C dating of peat bog VAL-III
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836 MX_HOT MT_AN MN_COL PR_WIN PR_SPR PR_SUM PR_AUT RAD_WIN RAD_SPR RAD_SUM RAD_AUT N
Fagus sylvatica 20.6-27.6 6.0-12.9 -5.9-3.1 121-509 166-449 94-330 139-436 338-1310 1978-2804 2656-3137 909-1935 3681
Abies alba 18.2- 26.4 3.5-10.4 -8.1, -1.1 139-385 212-395 186- 369 201-380 159-1345 1734-2799 2457-3133 652- 1968 614
837 838 839 840
Table 2. Ranging values from the predictors used in the GLM suitability models. The values presented avoid the lowest and highest 2.5% of values.
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841 Predicted Species R2
Nagelkerke Cut-off point Observed absence presence
CCR (a+d)/N
fpos b/(b+d)
fneg c((a+c)
absence 669 (a) 65 (b) Fagus sylvatica 0.84 0.30 presence 53 (c) 685 (d) 92% 0.09% 0.07%
0.91 absence 105 (a) 12 (b) Abies alba 0.55 presence 7 (c) 121 (d) 92% 0.09% 0.06% 842
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Table 3. Fitting and validation results from the Abies and Fagus suitability GLM models. CCR
(Correct classification rate) represents the general performance of the model. Fpos (False
positive rate) shows the percentage of suitability areas that do not match with present-day
distribution. This cannot be considered an error because exists suitability for both species. Fneg
(false negative rate) is the measure that can be considered as the error.