EFFECTS OF PYROGENIC FACTOR ON WETLANDS OF PETROVSKAYA PAD' (JEWISH AUTONOMOUS REGION, RUSSIA)
Tatyana A. Kopoteva, Victoria A. Kuptsova
Institute of Water and Ecology Problems FEB RAS, Russia e-mail: kopoteva@ivep.as.khb.ru, victoria@ivep.as.khb.ru
Received: 26.11.2018. Revised: 19.03.2019. Accepted: 23.04.2019.
In recent decades, a severe wildfire situation threatening the territory along the periphery of the Bastak State Nature Reserve (Russia) has developed in the Petrovskaya Pad'. In this paper, we assessed the current state of the vegetation cover and post-pyrogenic changes in the Petrovskaya Pad', based on the geobotanical survey during a joint expedition in 2009. At present, this area of the Middle Amur Lowland is a vivid example of wetland degradation due to the repeated wildfire impact initiated by the local people and agricultural workers in the Amur region. The widespread xerophytisation process of fen vegetation, due to a sharp drop in the groundwater level, was observed. A comparison with the data of previous studies led to the conclusions that now mesotrophic shrub-Sphagnum bogs, described earlier, have completely disappeared from the vegetation cover of the territory. We suggest that their degradation is caused by the continuously acting pyrogenic factor. In addition, the paper for the first time provides data on the dynamics of the acrotelm structure in the post-pyrogenic period, which were obtained during a nine-year monitoring. The profound changes in the acrotelm structure are responsible for the restoration of mesotrophic bogs taking decades.
Key words: acrotelm, biodiversity, mires, pyrogenic subclimax, uncontrolled fire
Introduction
The waterlogged area of the Middle Amur Lowland is approximately 50% (Prozorov et al., 1970). This is a landscape complex of mire ecosystems of eutrophic and mesotrophic types interspersed with forested hummocks. About half of the main territory of the State Nature Reserve «Bastak» (hereafter also - Bastak Reserve) is located in the southwestern part of the lowland. The plain part of the Bastak Reserve is heavily waterlogged. Among the mires, grass-Hypnum and Carex fens, and transitional dwarf-shrub-Sphagnum ones predominate. The monsoon character of precipitation leads to prolonged excessive soil moisture, winters with low snowfall, long-term preservation of seasonal frozen soil and deep freezing of the soil (150-200 cm), while poor permeability of clay soils contributes to the widespread occurrence of mires. Periods of heavy monsoon rains are often interchanged with long summer droughts. Because of this, brush fires here are very common. Prozorov (1985) considered this factor to be one of the main causes of thin peat deposits in the mires of the Middle Amur Lowland despite their old age. Peat deposit in the River Kiya basin has been dated to 9000 cal BP and that in the River Gur basin to 10 000-14 000 cal BP (Bazarova et al., 2018).
This part of the Jewish Autonomous Region was developed among the first in the region and has been used as an agricultural area since the beginning
of the 20th century. Traditionally, spring burning of the grass has been carried out as one of the agricultural practices generally accepted here. It usually turns into annual uncontrolled fires throughout the territory. In modern times, the fires have become a continuously acting factor affecting the extent and dynamics of forest and bog formation processes. A severe pyrogenic situation leading to alteration and depletion of vegetation cover has developed on the periphery of the Bastak Reserve. For this reason, in 2011 the Bastak Reserve administration established the cluster area «Zabelovsky» with the financial support of the Amur Branch of the World Wildlife Fund. The issue of assigning the status of the Protected Area to the Petrovskaya Pad' was rising many times. By that time, the landscapes of the Petrovskaya Pad', located between the Bastak Reserve and its cluster, had been already considered as an area with complete loss of their ecological functions (Kalinin, 2009). A local newspaper wrote: «The vast area of Petrovskaya Pad' has been famous for a wealth of flora and fauna only about three decades ago. Now there is little evidence of its former richness. Annual wildfires have not only destroyed a significant part of it, but also dried up all its water resources. It is clear that aquatic and riverside animals inhabited it had left the degraded zone. Having previously been swampy and impassable, Petrovskaya Pad' became literally dried up and covered with hard, dwarf and barren shrubs.
Members of the expedition of environmental scientists from Khabarovsk and Birobidzhan, visited Petrovskaya Pad' a few years ago, accurately noticed that it is possible to ride a bicycle here... And it entered such a state as soon as people stopped fighting fires here... (These priceless mires, 2015).
Profound changes in vegetation of the waterlogged areas of the Middle Amur Lowland, especially those that have undergone the earliest economic development, occur under the influence of the pyrogenic factor (Kopoteva, 2009). Because of frequently repeated fires, the vegetation cover of bogs in the Amur region is transformed into birch (Betula ovalifolia Rupr.) thickets devoid of Sphagnum cover (so-called «yerniki») (Kopoteva, 1999; Burenina, 2006). About 50-70% of the areas, previously occupied by dwarf-shrub-Sphagnum bogs with open larch stand (so-called «mari»), were transformed into Sphagnum-free yerniki in relatively densely populated areas in the south of the Khabarovsky Krai and in the Amur region.
The main biosphere function of the bogs (carbon deposition) is believed to be provided by Sphagnum mosses (Vitt, 2000; Benscoter & Vitt, 2008; Kosykh et al., 2009). They play primary a coenotic and peat-forming role in mires of this type. Among all the components of vegetation, the mosses make the largest contribution to carbon sequestration. By the end of the second year, over 90% of the production of all vascular plants in Sphagnum bogs is mineralised (Vishnyakova et al., 2012). At the same time, Sphagnum fuscum (Schimp.) H. Klinggr., predominated in the moss cover of the mesotrophic mires of the Amur region, decomposes only by 20% of the initial mass by the end of the first year and by another 10% two years later (Kozlovskaya et al., 1978; Germanova, 1983; Rochefort et al., 1990). The phytocoenoses are similar in vegetation structure to the mires of the Middle Amur Lowland. Studies of their productivity showed that the annual production of the moss layer (62%) is almost twice as much as the production of tree and herb-dwarf-shrub layers combined (38%) (Pyavchenko, 1967), and 3-4 times higher than the annual production of aboveground parts of plants of the same layers (Kopoteva, 1993; Knorre et al., 2007). Therefore, the pyrogenic factor leading to the irreversible loss of Sphagnum cover inflicts a serious damage to the biosphere.
The research on the effects of fires on the mire vegetation cover is very important. Numerous publications are devoted to this topic (e.g. Efre-mova & Efremov, 1994; Zoltai et al., 1998; Vom-
persky et al., 2007; Benscoter & Wieder, 2003). Peat fires make a substantial contribution to global greenhouse gas emissions, thus directly affecting the climate. Post-pyrogenic changes increase the drainage of peat and lead to the accumulation of combustible materials (dwarf shrubs). This increases the fire frequency (Furyaev et al., 2013), while a decrease in the moss productivity leads to a reduction in the rate of peat formation and long-term carbon accumulation (Turetsky et al., 2015).
The aim of this study was to establish the degree of vegetation cover transformation in the ecosystems of the Petrovskaya Pad' on the basis of geobotanical research and to compare it with the previously obtained data.
Material and Methods
The study area is located within 48.00-48.65° N and 133.20-133.90° E in the southwestern part of the Middle Amur Lowland between the River Bira and the lower reaches of the River In with relative heights of 48-54 m (Fig. 1). The total area of Petrovskaya Pad' is about 20 000 km2. According to climatic zoning, the territory belongs to the forest monsoon climatic zone of temperate latitudes. The harsh winter (-16 - -23°C) with low snowfall lasts for 4.5 months. 80% of the annual precipitation occurs in the second half of the summer. The distribution of precipitation is very uneven from year to year as well.
To assess the degree of vegetation cover transformation in comparison with the period before intensive agricultural development that started in the early 20th century, we used research data of botanists worked on the territory, which is now called the Jewish Autonomous Region. Korzhin-sky (1892) was one of the earliest researchers of the vegetation in the region. In 1892, the author wrote that a specific feature of the plain territory here is «the vast waterlogged areas». Mainly forest ecosystems were studied previously in this territory (Rubtsova, 2017). During the Soviet period, the peat bogs were described in detail in the north of the Petrovskaya Pad' (Kats, 1929). Soviet botanists carried out geobotanical research here (Vasi-lyev, 1937). But the most detailed study of the territory was conducted by Kurentsova (1967) with the creation of a geobotanical map. According to the results of Kurentsova's geobotanical zoning, the area (then known as Petrovskaya Mar') has been named as the «lowland In-Bira region of waterlogged open larch forests combined with fens and wet Calamagrostis-Carex meadows».
Fig. 1. The location of the Petrovskaya Pad' in the Russian Far East.
According to Kurentsova (1967), there are Sphagnum-dominated bogs and moss-Eriophorum and Carex mires, larch woodlands, which occupy more than 200 km2 in the valleys of many rivers in their middle reaches and on the interfluve of the River Amur and River In, in the lower reaches of the latter. The predominant vegetation of these mires consist of Sphagnum mosses. The mosses form a continuous carpet, although there are still small hollows in some places. The most common mosses are Sphagnum magellanicum Brid. and S. angustifollium (Warnst.) CEO Jensen. Near the water, the latter species is replaced by S. ambly-phyllum (Russow) Warnst. (currently - S. flexuo-sum Dozy & Molk). Sometimes, S. fuscum is found there. Kurentsova (1967) also provided the names of dominant vascular plant species, and thickness of deposit peat (from 30 cm to 1 m) «composed of Sphagnum, herbs and dwarf shrubs».
In June 2009, a joint expedition was carried out. Its purpose was to create a buffer zone of the cluster area «Zabelovsky» (a cluster of the Bastak Reserve) within the area of Petrovskaya Pad'. It is of crucial importance for the biodiversity conservation and the maintenance of seasonal bird migration (Averin, 2009; Kalinin, 2009). Two transects of 70 km each crossing the Petrovskaya Pad' from northwest to
southeast were made for that purpose. The main focus of the study was on phytocoenoses derived from mire communities in the course of post-fire succession. Sample plots of 10 x 10 m2 were laid in the phytocoenoses of uniform floristic composition. We performed 26 geobotanical descriptions of the phytocoenoses according to the standard methods (Ipatov & Mirin, 2008). We determined the boundaries of phytocoenoses, the species composition of vascular plants and mosses, the projective cover by species, their vitality, and the level of groundwater. Scientific names of plant species are given according to the Plant List (2013).
We collected peat samples from one deposit remaining after fires that is located 20 m from the shore of lake Krugloe. Drilling of the deposit to the mineral horizon was conducted using a Hiller drill. Peat samples were collected every 10 cm. The identification of the species composition of the plant remnants and the determination of their percentage ratio in peat samples were carried out using a microscope (Kats et al., 1977). Unfortunately, we could not get peat samples from other deposits because of the widespread occurrence of seasonal frozen soil.
In addition, for the first time, we used the data of nine-year monitoring of re-vegetation of
a mesotrophic dwarf shrub-Sphagnum bog in the south of the Middle Amur Lowland in the area of the settlement of Kiya (47.89° N, 135.65° E). The description of this object and the methods for assessing the phytomass dynamics during the initial phase of post-pyrogenic recovery were published in Kopoteva & Kuptsova (2016a).
Results
All sites of the Petrovskaya Pad' and adjacent territories were examined in detail during the expedition from 08 to 14 June 2009. Throughout most of the area the lack of water bodies and the degradation of wetlands were observed. The existing watercourses were experiencing a significant decrease in water level and were drying up. For example, the lakes of Petrovskaya Pad', Lake Krugloe, the lake in Petrunkin Sad, River Rassoshina, tributaries of River Petrovskaya have completely dried up. By the time of the survey, Petrovskaya Pad' was a plain area with hollows from former watercourses and dried-up oxbow lakes. It looked like a bare, drained, virtually lifeless, monotonous landscape.
Table 1 shows the species composition of described phytocoenoses that dominate there. It has
extremely low projective cover (PC) of herbaceous plant species (e.g. plot 7: 48.44916 N 133.62972 E, and plot 18: 48.74861 N 133.37972 E). It is not typical for grass ecosystems of the Middle Amur Lowland (Kopoteva, 1993). We observed a low vitality of all species, apart from the dominant ones. The species diversity in the meadow phytocoenoses was significantly depleted (e.g. plot 3, groundwater level (GWL) at -45 cm). The former quaking mires (e.g., in the mire Molchanikha, east of the village of Nayfeld), severely burnt, had indicators of the recent fires and are characterised by areas covered by Carex pseudocuraica F. Schmidt, and Comarum palustre L. lied directly on the frozen soil (plot 20). The GWL measured in these former mires was 30-40 cm below the surface. The height of the burnt Comarum palustre individuals did not exceed 10-15 cm. We noted a very low recovering of dominant plants and the introduction of non-typical species: Epilobium angustifolium L., Galium boreale L., Artemisia sp. In the central part of the Petrovskaya Pad' (near the Petrovskaya Sopka), we found areas of former bogs with burnt psychro-philic dwarf shrubs and remnants of Sphagnum hummocks. The projective cover of vascular plants (Carex sp.) did not exceed 10-20%.
Species Projective cover (PC) at sampling plots, % Species indices according to Ramensky's ecological scales (Seledets, 2011)
i-3, s-ii, i4, i6, i7, 23-25* 4-7, i9, 2i i3, i5, iS, i9, 22 i2, 20, 26
humidity trophicity
Anemonidium dichotomum Á. Löve & D. Löve i 57-89 7-14
Artemisia sp. i - -
Calamagrostis epigeios (L.) Roth. i 45-80 6-15
C. langsdorffii (Link) Trin. 20 10-25 54-97 4-15
C. stricta (Timm) Koeler i i 61-105 3-15
Carex appendiculata (Trautv.et Mey.) Kuk. 3 7 61-99 6-14
C. lasiocarpa Ehrh. 2 i0-20 61-104 4-13
C. meyeriana Kunth. 5 58-100 5-12
C. pseudocuraica F. Schmidt 15-30 5 i5 66-101 6-14
C. schmidttii Meinsh. 5 56-97 5-14
Caltha palustris var. membranacea Turcz. i i 63-85 8-11
Comarum palustre L. 3-5 30-60 61-102 4-13
Epilobium angustifolium L. i 52-94 3-13
Equisetum palustre L. i 59-100 4-15
Galium boreale L. i 50-94 6-15
Iris laevigata Fisch. i 63-104 4-13
Lysimachia thyrsiflora L. i 61-104 5-14
Pedicularis grandiflora Fisch. i 67-73 5-6
Ranunculus japonicus Thunb. i 58-94 8-13
Salix myrtilloides L. 3 5 61-98 4-13
Spiraea salicifolia L. i 52-94 4-14
Thalictrum amurense Maxim. i 60-75 9-11
PC of phytocoenosis 20-30 30-40 20-30 50-60
Note: *The descriptions were made in early June when many summer herbaceous species had not yet appeared.
Table 1. Composition and distribution of species and ecological characteristics of phytocoenoses in state of pyrogenic subclimax
All these phytocoenoses are in the stage of the pyrogenic subclimax of the ecosystems. In other words, they are long-term communities supported by recurring fires (Neshataev, 2013).
An analysis of the trophic index of species (Table 1) shows that almost all the plants currently growing there can withstand very poor acidic soils. Species predominant here are oligomesotrophytes and ortho-mesotrophytes (Seledets, 2011). These species are indicators of soils forming under wetland phytocoenoses.
Throughout the entire plain area of Petro-vskaya Pad', there is the unification of the vegetation cover described at the time by Vasiliev (1937) and Kurentsova (1967) as a multiplex landscape complex. In the second half of the 1960s, Kurentsova & Opritova (1975) described the replacement of Sphagnum open larch forests by dwarf birch thickets («yerniki») as a result of recurring fires. By the time of our survey, the vegetation cover on 2/3 of the area belonged to the meadow type and was dominated by Cala-magrostis langsdorffii with a projective cover of 20-30%, in some places 10-20% (Fig. 2). The rest of the open soil surface of meadows and fens, which is not occupied by vascular plants, is abundantly covered with fine brown mosses that serve as indicators of pyrogenic disorders: Ceratodon purpureus (Hedw.) Brid. and Cyn-odontium strumiferum (Hedw.) Lindb. Low hypsometric levels, such as hollows of former watercourses and dried-up oxbow lakes, are also occupied by fens with a very low projec-tive cover. Some part of the typical species of the mires (e.g. Caltha palustris var. membranacea Turcz., Equisetumpalustre L., Iris laevigata Fisch., Lysimachia thyrsiflora L.) have already disappeared. The rest of the species had a greatly reduced vitality. In some places, the surface of fens burnt up to ash-filled saucer-shaped depressions of up to 10 cm deep and 2-3 m in diameter with characteristic red traces of recent fires (Fig. 2). A complete absence of litter and dry grass typical for undisturbed grass mires of this region was also observed (Titlyanova et al., 1988).
The results of botanical analysis showed the presence of remnants of Sphagnum magellanicum (5%) and Drepanocladus sp. (20%), as well as Eri-ophorum sp. (15%), shrub bark (Chamaedaphne caliculata (L.) Moench and Salix myrtilloides) and bark of Larix gmelinii (Rupr.) Kuzen. at a depth of 40-50 cm and lower in the samples from deposits of Carex-dominated fens (plot 18) located
near Lake Krugloe (Fig. 3). Peat of 60-80 cm thick near the base of the deposit is composed mainly of Hypnales mosses such as Meesia triquetra (L. ex Jolycl.) Angstrom and Drepanocladus sp. with a little admixture of Sphagnum magellanicum. This confirms that a mire developing processes characteristic for the Middle Amur Lowland unaffected by human activity prevailed here in the past. At a depth of 40-50 cm of the peat deposit, charcoal particles as traces (indicators) of past fires were observed. Alluvium (quartz) was found at the base of the peat deposit.
Discussion
The studies show that the amount of carbon stored in mineral soils is several times lower than in waterlogged soils, and it is an order of magnitude lower than in the mires (Minaeva et al., 2008). Mire and wetland habitats have much larger carbon reserves due to the presence of peat deposits. They function as a long-term reservoir of atmospheric carbon. That is what determines the main biospheric function of the mires.
Herbal ecosystems of the Middle Amur Lowland are highly productive and get burned quite often. Due to the very large above-ground and underground production, they have a peaty horizon of up to 30-40 cm and a thick litter of up to 10 cm. The average annual stock of dried grass is 290 g/m2, the litter is 530 g/m2 (Titlyanova et al., 1988). The litter and dried grass recover within 2 years after the fire. Having lost them, the bare soil is exposed to deeper freezing at the conditions of severe winters in the Amur region. When measuring ground water levels during the expedition, in most places we found seasonal frozen soil at a depth of 5-10 cm from the surface.
Fig. 2. Burnt grass fen, after the fire impact in May 2009.
Fig. 3. Botanical composition of peat deposits of Carex fen in the vicinity of lake Krugloe.
Mesotrophic dwarf shrub-sphagnum larch-woods, the vegetation cover of which was described by Kurentsova (1967), in most cases have a peat deposit thickness of 50-80 cm here (Prozorov, 1985). They often burn as well, which is the topic of many publications. The deposits are composed mainly of fen and transitional peats. In particular, the peat of two-meter-deep deposit sampled in the Bastak reserve to the north of Petrovskaya Pad' is composed mainly of dwarf shrub-herbaceous lowland peat with admixture of Sphagnum mosses (Kopoteva, 2011). These mires have a much more complex structure than fens due to the symbiosis between Sphagnum mosses and psychrophilic shrubs. The unique structure of the vegetation cover of these mires can be preserved for a long period of time, since they are subclimax ecosystems (Popov, 2000). Under the continuous loose cover of living Sphagnum mosses (5-7 cm), an acrotelm of 30-35 cm thickness is located. It is an aerated horizon where the main processes of organic decomposition take place and peat formation begins.
In the course of the post-pyrogenic restoration of vegetation on mesotrophic mires, herbaceous plants and dwarf shrubs are restored in the first place. As shown in the mires in the basin of the river Kiya, the restoration of sphagnum mosses under favorable humidification conditions begins only in the sixth year (Kopoteva & Kuptsova, 2016b). Moreover, the process is affected by the
succession of brown mosses, especially those of the genus Polytrichum. The latter were able to replace Sphagnum, displacing them for a while from previous habitats in areas undisturbed by fire. (Kopoteva, 2019). But according to our observations, the duration of Polytrichum succession is relatively short in contrast to the meso-oligotrophic hydro-series after the post-pyrogenic recovery of mires dominated by Sphagna (Popov, 2000). An oligo-trophic Sphagnum cover is generally a cyclic succession that can exist for centuries (Kats, 1934). Fires do not only destroy the living moss cover, but also disturb the structure of the acrotelm. Our observations show that its recovery takes a much longer time than that of the structure of the aboveg-round phytomass. Fig. 4 shows the dynamics of the Sphagnum moss mortmass (without roots of vascular plants) in an acrotelm after the 2008 fire (Kopoteva & Kuptsova, 2016a). An acrotelm of the bog area undisturbed by fire is mainly represented by a fraction of poorly decomposed tirr that consist of moss stems with admixture of peat. In the burnt area, the upper part of the acrotelm was destroyed by the fire. The soil there was represented by peat and more decomposed tirr (fragments of Sphagnum stems and branches of a darker colour). The average density of these three fractions over the years of research in the non-burnt area was 1.5-2 times lower (2563.3 ± 128.2 g/m2) than that on the burnt one (4847 ± 335.4 g/m2).
Fig. 4. Dynamics of the sums of positive temperatures and precipitation (a); dynamics of tirr of a low (b) and a high (c) degree of decomposition and of peat (d) in a layer of 0-30 cm in the undisturbed and burnt areas of the bog in the vicinity of the Kiya settlement.
Previously, we estimated the burnt Sphagnum mortmass (of low decomposition degree in the horizon of 0-20 cm) at 777 ± 82 g/m2 taking into account the mosaic pattern of the burning (Kopoteva & Kuptsova, 2016 a). Comparing the difference of the values of this fraction in 2012 with the undisturbed and burnt parts of the mire, we obtain a similar value of 831.5 ± 141.2 g/m2.
The dynamics of the structure of the acrotelm on the undisturbed area is weakly expressed. In spring 2014, a fire did not touch the areas that were left unburnt in 2008. A reduction in the inflow of the tirr of a low degree of decomposition in 2017 can be explained by a rapid expansion of Polytrichum strictum that increased after the fire (Kopoteva, 2019). After 2014, the peat mass
increased in samples from the burnt area. This is most likely due to an increase in the mosaicity of microtopography after the catastrophic fire in 2008. However, as we can see, due to the state of the acrotelm structure in 2017, the process of its complete restoration would take a long time. It largely depends on the production of restored Sphagnum mosses.
Botanical analysis of peat acrotelm of the burnt area in 2012-2013 showed that it consists of Sphagnum remnants and dwarf shrubs (2060%), as well as small bryophytes (15-20%) and a small amount of Eriophorum. The further analysis showed an increasing number of remnants of dwarf shrubs, brown mosses and Eriophorum. The degree of peat decomposition was increasing.
An analysis of the peat deposit stratigraphy at the Petrovskaya Pad' provides evidence that the direction of change of bog vegetation in the process of changes in the hydrological regime is typical of the Middle Amur Lowland. It is very likely that the formation of the mire has begun in the sub-atlantic period of the Holocene (Neishtadt, 1957; Khotinsky, 1977). The formation of peat-forming mires on the territory of Petrovskaya Pad' has begun after the cessation of the flood regime, which is evidenced by the presence of alluvium (quartz) and the change of priority in the composition of the vegetation from hydrophytes to hygrophytes. This is a classic change of an overgrown reservoir with a moss (in this case, Hypnum) mire.
The presence of the remnants of Sphagnum mosses, dwarf shrubs and larch bark in peat indicates the existence of mesotrophic shrub-Sphagnum larchwood at a certain stage of the mire-forming process. Mires of this type can be found in the environment of grassy ecosystems, which is confirmed by the data of Kurentsova (1967). We did not see them during the geobotanical survey of the modern vegetation cover of the Petrovskaya Pad'.
Conclusions
Thus, as a result of uncontrolled annual burning on the territory between the rivers Bira-In, In-Amur, a special dynamic state of ecosystems was formed. It is an example of a pyrogenic subclimax or a complex of secondary permanent associations developed as a result of recurring fires (Neshataev, 2013).
Moss-dominated ecosystems that are capable of taking up and storing large amounts of carbon have completely disappeared and probably will not recover. Their biodiversity has significantly decreased. With the disappearance of shrub-Sphagnum peat-forming ecosystems, the habitats of the species listed in the Red Data Book of the Jewish Autonomous Region (2006) have been greatly reduced in size. It concerns, for instance, the following species: Pogonia japonica Rchb.f., Spiranthes sinensis (Pers.) Ames, and other hygrophytes such as Parnassiapalustris L., Menyanthes trifoliata L., Vaccinium microcarpum (Turcz. Ex Rupr.) Schm-alh., and Vaccinium oxycoccos L., Comarumpalus-tre, Lobelia sessilifolia Lamb. All species except the last one are medicinal plants (Rubtsova, 2017). The elimination of wetlands as well drying of fens and bogs on the territory of Petrovskaya Pad' led to a reduction in the number of species of wild animals and the destruction of places suitable for nesting of Ciconia boyciana Swinhoe, 1873. They are the wet-
lands that influence the formation of climatic conditions in most of the region. They accumulate and store fresh water, maintain the level of groundwater, return oxygen to the atmosphere, provide the River Amur with clean water from the waterlogged flood-plain. It is enough to say that only from the territory of the Jewish Autonomous Region some 5000 medium and small rivers supply clean water directly or through large tributaries into the River Amur. It is not an accident that the wetlands of the South of the Russian Far East, including the Jewish Autonomous Region, are in the Ramsar List of Wetlands of International Importance that contains only 35 sites from Russia. Ramsar Wetlands are those that need special protection and conservation.
In 2013, in the River Amur valley there was a flood which caused an enormous economic damage, but, according to local ecologists, it «revived the environment» of the Petrovskaya Pad'. The flooding brought high amounts of water to this dried-up territory, the area became saturated with water, and it began to gradually come to life, returning its former ecological value. According to the locals, the quaking mires where they used to harvest Comarum palustre began to recover. However, the restoration of the mires here is possible only if the control is established over the annual agricultural burning. The problem is that the burning is still turning into catastrophic fires destroying remnants of peat deposits throughout the territory of the Petrovskaya Pad'.
Acknowledgements
The authors are grateful to the administration of the Bastak State Nature Reserve, in particular to its director A.Yu. Kalinin, as well as to the senior researcher of the Institute for Complex Analysis of Regional Problems of Far Eastern Branch of RAS (ICARP FEB RAS), T.A. Rubtsova, for the opportunity to collect field material.
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ПОСЛЕДСТВИЯ ПИРОГЕННОГО ФАКТОРА ДЛЯ ВОДНО-БОЛОТНЫХ УГОДИЙ ПЕТРОВСКОЙ ПАДИ (ЕВРЕЙСКАЯ АВТОНОМНАЯ ОБЛАСТЬ, РОССИЯ)
Т. А. Копотева, В. А. Купцова
Институт водных и экологических проблем ДВО РАН, Россия e-mail: kopoteva@ivep.as.khb.ru, victoria@ivep.as.khb.ru
В последние десятилетия по периферии заповедника Бастак в урочище Петровская падь сложилась тяжелая пирогенная обстановка, угрожающая территории заповедника. По материалам геоботанического обследования Петровской пади, сделанного в ходе совместной экспедиции в 2009 г., дается оценка современного состояния растительного покрова и постпирогенных изменений. В настоящее время этот район Средне-амурской низменности является ярким примером деградации водно-болотных угодий (ВБУ) в результате многократного воздействия палов, применяющихся в Приамурье населением и работниками сельского хозяйства. Отмечено широкое распространение процесса ксеризации растительности травяных болот из-за резкого снижения уровня грунтовых вод. Проанализированы материалы предыдущих исследователей, которые привели к выводу, что из растительного покрова территории полностью исчезли мезотрофные кустарничково-сфагновые болота, ранее описывавшиеся Г. Э. Куренцовой. Их деградация объясняется авторами постоянно действующим пирогенным фактором. Впервые приводятся данные динамики структуры акротельма в постпирогенный период, полученные в ходе девятилетнего мониторинга. Глубокие изменения в структуре акротельма приводят к тому, что восстановление мезотрофных болот занимает десятки лет.
Ключевые слова: акротельм, биоразнообразие, болота, неконтролируемые палы, пирогенный субклимакс