{"title":"Heracleum sosnowskyi Manden社区。在库尔斯克地区","authors":"L. Arepieva","doi":"10.31111/vegrus/2022.43.5","DOIUrl":null,"url":null,"abstract":"Classification of communities with Heracleum sosnovskyi in the Kursk Region (Table 1), based on 43 relevés, made by the author in 2014–2020 in some locations mainly in the western part of the study area (Fig. 1), is carried out according to Braun-Blanquet approach. The data are treated by IBIS 7.2 software package (Zverev, 2007). The names of the higher syntaxa follow to «Vegetation of Europe…» (Mucina et al., 2016). Synoptic tables include only species with constancy above I. Soil moisture, reaction, richness in mineral nitrogen, light, temperature and continentality are assessed using mean H. Ellenberg ecological indicator values (Ellenberg et al. 1992), hemeroby — with these of N. G. Ilminskikh ecological 9-point scale (Ilminskikh, 1993). Significant differences between pairs of syntaxa for each environmental factor are determined by the Mann-Whitney U-test in the PAST package (Hammer et al. 2001). 3 associations, 2 variants and 1 derivative community of 3 classes of vegetation are established. Ass. Chelidonio–Aceretum negundi L. Ishbirdina in L. Ishbirdina et al. 1989, var. Heracleum sosnowskyi (Table 2, Fig. 2). The association belongs to alliance Chelidonio–Acerion negundi L. Ishbirdina et A. Ishbirdin 1989, order Chelidonio–Robinietalia pseudoacaciae Jurco ex Hadač et Sofron 1980, class Robinietea Jurco ex Hadač et Sofron 1980. DS of the association are Acer negundo, Chelidonium majus, that of the variant is Heracleum sosnowskyi. Communities most often have three layers. The tree layer is dominated by Acer negundo with 7–20 m heigh and 50–90 % canopy density. The shrub layer (1–3 m, 1–50 %) is dominated by Acer negundo undergrowth, sometimes there are Padus avium, Populus alba, Prunus domestica, Sambucus nigra, S. racemosa, Ulmus glabra. The herb-dwarf shrub layer (height – 70–150 cm, plant cover – 50–100 %) is dominated by Heracleum sosnowskyi, mainly by its vegetative shoots. Generative shoots are found mainly in the most sunlit sites. There are 68 species in the association with 7–21 species per sample plot. The communities formed as a result of H. sosnowskyi penetration into phytocenoses of the var. typica ass. Chelidonio–Aceretum negundi are common in wastelands, along roads and banks of reservoirs, near abandoned houses in villages. There are slight differences in habitats of variants Heracleum sosnowskyi and typica (Fig. 3, Table 4): communities of the first one inhabit wetter soils, while these of the var. typica have the higher levels of temperature, continentality and hemerobiality, that is why there is a lot annuals and biennials, many of which are continental thermophilic species and belong to eu- and polyhemerobes (Lactuca serriola, Atriplex tatarica, Arctium tomentosumи др.). H. sosnowskyi exists even in heavily shaded areas. The species composition of communities of the var. Heracleum sosnowskyi is quite stable which is facilitated by the flow of seeds from surroundings and the capacity of germination of those seeds that did not germinate in the first year, as well as the ability of specimens to exist in a vegetative state for a long time under unfavorable conditions (Vinogradova et al., 2010; Panasenko, 2017). Ass. Urtico dioicae–Heracleetum sosnowskyi Panasenko et al. 2014 (Table. 5, rel. 1–17, Fig. 4). The association belongs to alliance Aegopodion podagrariae Tx. 1967 nom. conserv. propos., order Circaeo lutetianae–Stachyetalia sylvaticae Passarge 1967 nom. conserv. propos., class Epilobietea angustifolii Tx. et Preising ex von Rochow 1951. DS: Heracleum sosnowskyi, Urtica dioica. The total plant cover is 80–100 %. Communities have three sub-levels: the upper one (1.0–1.5 m) is of Heracleum sosnowskyi generative shoots; the mid one (1–1.5 m) is of its leaves; the lower one is of herbs Anthriscus sylvestris, Arctium tomentosum, Artemisia vulgaris, Ballota nigra, Cirsium arvense, Dactylis glomerata, Elytrigia repens, Galium aparine and Urtica dioica. There are 83 species in the association, with 9–29 species per sample plot. Such communities, formed as a result of Heracleum sosnowskyi invasion into phytocenoses of the class Epilobietea angustifolii, often occur in anthropogenic habitats. Derivative community Heracleum sosnowskyi [Agropyretalia intermedio–repentis] (Table. 5, rel. 18–25, Fig. 5). DS: Heracleum sosnowskyi. The total plant cover is 85–100 %. Communities have three sub-levels, just like in the previous syntaxon. However, in contrast to it, species of Artemisietea vulgaris Lohmeyer et al. in Tx. ex von Rochow 1951 prevail in the derivative community (Table. 6). Species of order Agropyretalia intermedio–repentis T. Müller et Görs 1969 are represented with high constancy. Such communities, formed as a result of Heracleum sosnowskyi invasion into phytocenoses of this order, occur along roads, in wastelands, on dry meadows. There are 68 species in the community coenoflora, with 7–30 species per sample plot. There are differences in habitats of this derivative community and the ass. Urtico dioicae–Heracleetum sosnowskyi (Fig. 6, Table 7). Communities of the association often inhabit wetter and eutrophic soils, while derivative ones are common in more sunlit and heated sites. Ass. Rudbeckio laciniatae–Solidaginetum canadensis Tüxen et Raabe ex Anioł-Kwiatkowska 1974, var. Heracleum sosnowskyi (Table. 5, rel. 26–31, Fig. 7). The association belongs to alliance Dauco-Melilotion Görs ex Rostański et Gutte 1971, order Onopordetalia acanthii Br.-Bl. et Tx. ex Klika et Hadač 1944, class Artemisietea vulgaris. DS of the association is Solidago сanadensis, this of the variant is Heracleum sosnowskyi. Both are dominating species. The total plant cover is 100 %. Phytocenoses have three sub-levels: the upper one (up to 3 m high) is of H. sosnowskyi generative shoots; the mid one (1.0–1.5 m) is of its leaves (sometimes quite numerous) and of Solidago сanadensis; the lower one (up to 0.5 m high) is of Heracleum sosnowskyi seedlings, as well as of Achillea millefolium, Carex hirta, Equisetum arvense and Poa angustifolia with lower cover. There are 48 species in the association, with 12–18 species per sample plot. Such communities common in the northwestern part of the Kursk region occur in wastelands, along roads and banks of reservoirs. They appeared as a result of Heracleum sosnowskyi penetration into phytocenoses of the ass. Rudbeckio laciniatae–Solidaginetum canadensis (Fig. 8), as well as with concurrent spread of both Heracleum sosnowskyi and Solidago сanadensis on the territory (Fig. 9). In spite of significant differences in soil moisture and temperature, in general, habitats of variants Solidago сanadensis and Heracleum sosnowskyi of the ass. Rudbeckio laciniatae–Solidaginetum canadensis are rather similar (Fig. 10, Table 8). There are fewer xeromesophytes of the order Onopordetalia acanthii and more species of the class Epilobietea angustifolii in the species composition of the var. Heracleum sosnowskyi (Table 9).","PeriodicalId":37606,"journal":{"name":"Rastitel''nost'' Rossii","volume":"1 1","pages":""},"PeriodicalIF":0.0000,"publicationDate":"2022-01-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":"{\"title\":\"Communities with Heracleum sosnowskyi Manden. in the Kursk Region\",\"authors\":\"L. Arepieva\",\"doi\":\"10.31111/vegrus/2022.43.5\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"Classification of communities with Heracleum sosnovskyi in the Kursk Region (Table 1), based on 43 relevés, made by the author in 2014–2020 in some locations mainly in the western part of the study area (Fig. 1), is carried out according to Braun-Blanquet approach. The data are treated by IBIS 7.2 software package (Zverev, 2007). The names of the higher syntaxa follow to «Vegetation of Europe…» (Mucina et al., 2016). Synoptic tables include only species with constancy above I. Soil moisture, reaction, richness in mineral nitrogen, light, temperature and continentality are assessed using mean H. Ellenberg ecological indicator values (Ellenberg et al. 1992), hemeroby — with these of N. G. Ilminskikh ecological 9-point scale (Ilminskikh, 1993). Significant differences between pairs of syntaxa for each environmental factor are determined by the Mann-Whitney U-test in the PAST package (Hammer et al. 2001). 3 associations, 2 variants and 1 derivative community of 3 classes of vegetation are established. Ass. Chelidonio–Aceretum negundi L. Ishbirdina in L. Ishbirdina et al. 1989, var. Heracleum sosnowskyi (Table 2, Fig. 2). The association belongs to alliance Chelidonio–Acerion negundi L. Ishbirdina et A. Ishbirdin 1989, order Chelidonio–Robinietalia pseudoacaciae Jurco ex Hadač et Sofron 1980, class Robinietea Jurco ex Hadač et Sofron 1980. DS of the association are Acer negundo, Chelidonium majus, that of the variant is Heracleum sosnowskyi. Communities most often have three layers. The tree layer is dominated by Acer negundo with 7–20 m heigh and 50–90 % canopy density. The shrub layer (1–3 m, 1–50 %) is dominated by Acer negundo undergrowth, sometimes there are Padus avium, Populus alba, Prunus domestica, Sambucus nigra, S. racemosa, Ulmus glabra. The herb-dwarf shrub layer (height – 70–150 cm, plant cover – 50–100 %) is dominated by Heracleum sosnowskyi, mainly by its vegetative shoots. Generative shoots are found mainly in the most sunlit sites. There are 68 species in the association with 7–21 species per sample plot. The communities formed as a result of H. sosnowskyi penetration into phytocenoses of the var. typica ass. Chelidonio–Aceretum negundi are common in wastelands, along roads and banks of reservoirs, near abandoned houses in villages. There are slight differences in habitats of variants Heracleum sosnowskyi and typica (Fig. 3, Table 4): communities of the first one inhabit wetter soils, while these of the var. typica have the higher levels of temperature, continentality and hemerobiality, that is why there is a lot annuals and biennials, many of which are continental thermophilic species and belong to eu- and polyhemerobes (Lactuca serriola, Atriplex tatarica, Arctium tomentosumи др.). H. sosnowskyi exists even in heavily shaded areas. The species composition of communities of the var. Heracleum sosnowskyi is quite stable which is facilitated by the flow of seeds from surroundings and the capacity of germination of those seeds that did not germinate in the first year, as well as the ability of specimens to exist in a vegetative state for a long time under unfavorable conditions (Vinogradova et al., 2010; Panasenko, 2017). Ass. Urtico dioicae–Heracleetum sosnowskyi Panasenko et al. 2014 (Table. 5, rel. 1–17, Fig. 4). The association belongs to alliance Aegopodion podagrariae Tx. 1967 nom. conserv. propos., order Circaeo lutetianae–Stachyetalia sylvaticae Passarge 1967 nom. conserv. propos., class Epilobietea angustifolii Tx. et Preising ex von Rochow 1951. DS: Heracleum sosnowskyi, Urtica dioica. The total plant cover is 80–100 %. Communities have three sub-levels: the upper one (1.0–1.5 m) is of Heracleum sosnowskyi generative shoots; the mid one (1–1.5 m) is of its leaves; the lower one is of herbs Anthriscus sylvestris, Arctium tomentosum, Artemisia vulgaris, Ballota nigra, Cirsium arvense, Dactylis glomerata, Elytrigia repens, Galium aparine and Urtica dioica. There are 83 species in the association, with 9–29 species per sample plot. Such communities, formed as a result of Heracleum sosnowskyi invasion into phytocenoses of the class Epilobietea angustifolii, often occur in anthropogenic habitats. Derivative community Heracleum sosnowskyi [Agropyretalia intermedio–repentis] (Table. 5, rel. 18–25, Fig. 5). DS: Heracleum sosnowskyi. The total plant cover is 85–100 %. Communities have three sub-levels, just like in the previous syntaxon. However, in contrast to it, species of Artemisietea vulgaris Lohmeyer et al. in Tx. ex von Rochow 1951 prevail in the derivative community (Table. 6). Species of order Agropyretalia intermedio–repentis T. Müller et Görs 1969 are represented with high constancy. Such communities, formed as a result of Heracleum sosnowskyi invasion into phytocenoses of this order, occur along roads, in wastelands, on dry meadows. There are 68 species in the community coenoflora, with 7–30 species per sample plot. There are differences in habitats of this derivative community and the ass. Urtico dioicae–Heracleetum sosnowskyi (Fig. 6, Table 7). Communities of the association often inhabit wetter and eutrophic soils, while derivative ones are common in more sunlit and heated sites. Ass. Rudbeckio laciniatae–Solidaginetum canadensis Tüxen et Raabe ex Anioł-Kwiatkowska 1974, var. Heracleum sosnowskyi (Table. 5, rel. 26–31, Fig. 7). The association belongs to alliance Dauco-Melilotion Görs ex Rostański et Gutte 1971, order Onopordetalia acanthii Br.-Bl. et Tx. ex Klika et Hadač 1944, class Artemisietea vulgaris. DS of the association is Solidago сanadensis, this of the variant is Heracleum sosnowskyi. Both are dominating species. The total plant cover is 100 %. Phytocenoses have three sub-levels: the upper one (up to 3 m high) is of H. sosnowskyi generative shoots; the mid one (1.0–1.5 m) is of its leaves (sometimes quite numerous) and of Solidago сanadensis; the lower one (up to 0.5 m high) is of Heracleum sosnowskyi seedlings, as well as of Achillea millefolium, Carex hirta, Equisetum arvense and Poa angustifolia with lower cover. There are 48 species in the association, with 12–18 species per sample plot. Such communities common in the northwestern part of the Kursk region occur in wastelands, along roads and banks of reservoirs. They appeared as a result of Heracleum sosnowskyi penetration into phytocenoses of the ass. Rudbeckio laciniatae–Solidaginetum canadensis (Fig. 8), as well as with concurrent spread of both Heracleum sosnowskyi and Solidago сanadensis on the territory (Fig. 9). In spite of significant differences in soil moisture and temperature, in general, habitats of variants Solidago сanadensis and Heracleum sosnowskyi of the ass. Rudbeckio laciniatae–Solidaginetum canadensis are rather similar (Fig. 10, Table 8). There are fewer xeromesophytes of the order Onopordetalia acanthii and more species of the class Epilobietea angustifolii in the species composition of the var. Heracleum sosnowskyi (Table 9).\",\"PeriodicalId\":37606,\"journal\":{\"name\":\"Rastitel''nost'' Rossii\",\"volume\":\"1 1\",\"pages\":\"\"},\"PeriodicalIF\":0.0000,\"publicationDate\":\"2022-01-01\",\"publicationTypes\":\"Journal Article\",\"fieldsOfStudy\":null,\"isOpenAccess\":false,\"openAccessPdf\":\"\",\"citationCount\":\"0\",\"resultStr\":null,\"platform\":\"Semanticscholar\",\"paperid\":null,\"PeriodicalName\":\"Rastitel''nost'' Rossii\",\"FirstCategoryId\":\"1085\",\"ListUrlMain\":\"https://doi.org/10.31111/vegrus/2022.43.5\",\"RegionNum\":0,\"RegionCategory\":null,\"ArticlePicture\":[],\"TitleCN\":null,\"AbstractTextCN\":null,\"PMCID\":null,\"EPubDate\":\"\",\"PubModel\":\"\",\"JCR\":\"Q4\",\"JCRName\":\"Agricultural and Biological Sciences\",\"Score\":null,\"Total\":0}","platform":"Semanticscholar","paperid":null,"PeriodicalName":"Rastitel''nost'' Rossii","FirstCategoryId":"1085","ListUrlMain":"https://doi.org/10.31111/vegrus/2022.43.5","RegionNum":0,"RegionCategory":null,"ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"Q4","JCRName":"Agricultural and Biological Sciences","Score":null,"Total":0}
引用次数: 0
摘要
根据作者2014-2020年在研究区西部部分地点(图1)的43份相关数据(Fig. 1),对库尔斯克地区sosnovskyi Heracleum群落进行分类(表1)。数据采用IBIS 7.2软件包(Zverev, 2007)处理。高等句法群的名称遵循“欧洲植被…”(Mucina et al., 2016)。概观表仅包括稳定性高于1的物种。土壤湿度、反应、矿物氮丰富度、光照、温度和大陆性采用H. Ellenberg生态指标值平均值(Ellenberg et al. 1992)和N. G. Ilminskikh生态9分制(Ilminskikh, 1993)进行评估。每种环境因素对句法的显著差异由PAST软件包中的Mann-Whitney u检验确定(Hammer et al. 2001)。建立了3类植被的3个关联、2个变异和1个衍生群落。chelidonio - acertum negundi L. Ishbirdina in L. Ishbirdina etal . 1989, var. Heracleum sosnowskyi(表2,图2)。该协会隶属于Chelidonio-Acerion negundi L. Ishbirdina et A. Ishbirdin 1989, Chelidonio-Robinietalia pseudoacacae Jurco ex hadaset Sofron 1980, Robinietea Jurco ex hadaset Sofron 1980。与之相关的DS是黑槭、白屈苣苔,变种是白屈苣苔。社区通常有三层。乔木层以宏木为主,乔木高7 ~ 20 m,乔木密度50 ~ 90%。灌木层(1 ~ 3 m, 1 ~ 50%)以黑槭为主,间或有柏树、白杨、家李、黑树、总状松、秃榆。草本-矮灌木层(高- 70 ~ 150 cm,盖度- 50 ~ 100%)以雪棘属植物(Heracleum sosnowskyi)为主,以营养枝为主。生芽主要生长在阳光最充足的地方。群落共有68种,每个样地有7 ~ 21种。在荒地、公路沿线、水库岸边、村庄废弃房屋附近,由于H. sosnowskyi渗透到典型的Chelidonio-Aceretum negundi的植物群落中而形成的群落很常见。在生境上有轻微的差异(图3,表4):第一种类型的群落居住在较湿润的土壤中,而典型类型的群落具有较高的温度水平、大陆性和萱草性,这就是为什么有很多一年生和二年生植物,其中许多是大陆嗜热物种,属于eu-和多萱草(Lactuca serriola, Atriplex tatarica, Arctium tomentosumva др.)。H. sosnowskyi甚至存在于阴影浓重的地区。白毛杨群落的物种组成相当稳定,这主要得益于来自周围环境的种子流动和第一年未发芽的种子的萌发能力,以及标本在不利条件下长期处于植物状态的能力(Vinogradova et al., 2010;Panasenko, 2017)。as。Urtico dioicae-Heracleetum sosnowskyi Panasenko et al. 2014(表5,rel. 1-17,图4).该协会隶属于联盟Aegopodion podagrariae Tx. 1967 nomo . conservv。言之凿凿。,林次:林次:林次目:林次1967言之凿凿。,分类:结肠镜下的结肠镜下的结肠镜下的结肠镜下的结肠镜。赫拉克利姆·索斯诺斯基,《荨荨病》。总植被覆盖率为80 - 100%。群落有3个亚层:上层(1.0 ~ 1.5 m)为白雪莲生芽;中间的一个(1-1.5米)是它的叶子;排名靠后的草本植物为:炭黑、牛蒡、蒿、黑球藻、羊角草、鸭茅、凤尾草、凤尾草、凤尾草、凤尾草、凤尾草、凤尾草和荨麻。群落共有物种83种,每个样地有9 ~ 29种。这类群落通常发生在人为生境中,是由白毛藻(Heracleum sosnowskyi)侵入叶豆(Epilobietea angustifolii)类植物群落形成的。衍生群落Heracleum sosnowskyi [Agropyretalia intermedio-repentis](表5,rel. 18-25,图5)。总植被覆盖率为85 - 100%。社区有三个子级别,就像前面的语法一样。然而,与之相反,在衍生群落中,Artemisietea vulgaris Lohmeyer et al. in txt . ex von Rochow 1951中占优势的物种(表6)。Agropyretalia intermedio-repentis T. mller et Görs 1969中的物种具有较高的稳定性。这样的群落,是由雪雪菌侵入这一目植物群落而形成的,分布在道路、荒地和干燥的草地上。群落群落共有68种,每个样地有7 ~ 30种。 根据作者2014-2020年在研究区西部部分地点(图1)的43份相关数据(Fig. 1),对库尔斯克地区sosnovskyi Heracleum群落进行分类(表1)。数据采用IBIS 7.2软件包(Zverev, 2007)处理。高等句法群的名称遵循“欧洲植被…”(Mucina et al., 2016)。概观表仅包括稳定性高于1的物种。土壤湿度、反应、矿物氮丰富度、光照、温度和大陆性采用H. Ellenberg生态指标值平均值(Ellenberg et al. 1992)和N. G. Ilminskikh生态9分制(Ilminskikh, 1993)进行评估。每种环境因素对句法的显著差异由PAST软件包中的Mann-Whitney u检验确定(Hammer et al. 2001)。建立了3类植被的3个关联、2个变异和1个衍生群落。chelidonio - acertum negundi L. Ishbirdina in L. Ishbirdina etal . 1989, var. Heracleum sosnowskyi(表2,图2)。该协会隶属于Chelidonio-Acerion negundi L. Ishbirdina et A. Ishbirdin 1989, Chelidonio-Robinietalia pseudoacacae Jurco ex hadaset Sofron 1980, Robinietea Jurco ex hadaset Sofron 1980。与之相关的DS是黑槭、白屈苣苔,变种是白屈苣苔。社区通常有三层。乔木层以宏木为主,乔木高7 ~ 20 m,乔木密度50 ~ 90%。灌木层(1 ~ 3 m, 1 ~ 50%)以黑槭为主,间或有柏树、白杨、家李、黑树、总状松、秃榆。草本-矮灌木层(高- 70 ~ 150 cm,盖度- 50 ~ 100%)以雪棘属植物(Heracleum sosnowskyi)为主,以营养枝为主。生芽主要生长在阳光最充足的地方。群落共有68种,每个样地有7 ~ 21种。在荒地、公路沿线、水库岸边、村庄废弃房屋附近,由于H. sosnowskyi渗透到典型的Chelidonio-Aceretum negundi的植物群落中而形成的群落很常见。在生境上有轻微的差异(图3,表4):第一种类型的群落居住在较湿润的土壤中,而典型类型的群落具有较高的温度水平、大陆性和萱草性,这就是为什么有很多一年生和二年生植物,其中许多是大陆嗜热物种,属于eu-和多萱草(Lactuca serriola, Atriplex tatarica, Arctium tomentosumva др.)。H. sosnowskyi甚至存在于阴影浓重的地区。白毛杨群落的物种组成相当稳定,这主要得益于来自周围环境的种子流动和第一年未发芽的种子的萌发能力,以及标本在不利条件下长期处于植物状态的能力(Vinogradova et al., 2010;Panasenko, 2017)。as。Urtico dioicae-Heracleetum sosnowskyi Panasenko et al. 2014(表5,rel. 1-17,图4).该协会隶属于联盟Aegopodion podagrariae Tx. 1967 nomo . conservv。言之凿凿。,林次:林次:林次目:林次1967言之凿凿。,分类:结肠镜下的结肠镜下的结肠镜下的结肠镜下的结肠镜。赫拉克利姆·索斯诺斯基,《荨荨病》。总植被覆盖率为80 - 100%。群落有3个亚层:上层(1.0 ~ 1.5 m)为白雪莲生芽;中间的一个(1-1.5米)是它的叶子;排名靠后的草本植物为:炭黑、牛蒡、蒿、黑球藻、羊角草、鸭茅、凤尾草、凤尾草、凤尾草、凤尾草、凤尾草、凤尾草和荨麻。群落共有物种83种,每个样地有9 ~ 29种。这类群落通常发生在人为生境中,是由白毛藻(Heracleum sosnowskyi)侵入叶豆(Epilobietea angustifolii)类植物群落形成的。衍生群落Heracleum sosnowskyi [Agropyretalia intermedio-repentis](表5,rel. 18-25,图5)。总植被覆盖率为85 - 100%。社区有三个子级别,就像前面的语法一样。然而,与之相反,在衍生群落中,Artemisietea vulgaris Lohmeyer et al. in txt . ex von Rochow 1951中占优势的物种(表6)。Agropyretalia intermedio-repentis T. mller et Görs 1969中的物种具有较高的稳定性。这样的群落,是由雪雪菌侵入这一目植物群落而形成的,分布在道路、荒地和干燥的草地上。群落群落共有68种,每个样地有7 ~ 30种。 这一衍生群落的生境与乌拉科(Urtico dioicae-Heracleetum sosnowskyi)存在差异(图6,表7)。该协会的群落通常居住在湿润和富营养化的土壤中,而衍生群落通常生活在阳光充足和温度较高的地方。Rudbeckio laciniatae-Solidaginetum canadensis t<e:1> xen et Raabe ex Anioł-Kwiatkowska 1974, var. Heracleum sosnowskyi(表5,rel. 26-31,图7).该关联属于alliance -Dauco-Melilotion Görs ex Rostański et Gutte 1971,目Onopordetalia acanthii Br.-Bl。et txex Klika和hadasei 1944,蒿属。该关联的DS是Solidago <s:1> anadensis,这个变种是Heracleum sosnowskyi。两者都是优势物种。总植被覆盖率为100%。植物苔藓有三个亚层:最上层(高达3米)为雪梨生殖芽;中间的一个(1.0-1.5米)是它的叶子(有时相当多)和苏达戈(Solidago);较低的一层(最高可达0.5米)是雪莲幼苗,以及有下盖的千叶阿喀琉叶、毛蕊草、木贼草和木犀草幼苗。群落共有48种,每个样地有12 ~ 18种。这种群落在库尔斯克地区西北部很常见,分布在荒地、公路沿线和水库岸边。它们的出现是由于白毛茛渗透到驴的植物丛中(图8),以及白毛茛和黄毛茛在领土上同时传播(图9)。尽管土壤湿度和温度存在显著差异,但总体而言,黄毛茛变种和黄毛茛变种的生境相当相似(图10)。表8).在白棘棘变种的物种组成中,干生植物Onopordetalia acanthii目较少,而Epilobietea angustifolii纲种类较多(表9)。 这一衍生群落的生境与乌拉科(Urtico dioicae-Heracleetum sosnowskyi)存在差异(图6,表7)。该协会的群落通常居住在湿润和富营养化的土壤中,而衍生群落通常生活在阳光充足和温度较高的地方。Rudbeckio laciniatae-Solidaginetum canadensis t<e:1> xen et Raabe ex Anioł-Kwiatkowska 1974, var. Heracleum sosnowskyi(表5,rel. 26-31,图7).该关联属于alliance -Dauco-Melilotion Görs ex Rostański et Gutte 1971,目Onopordetalia acanthii Br.-Bl。et txex Klika和hadasei 1944,蒿属。该关联的DS是Solidago <s:1> anadensis,这个变种是Heracleum sosnowskyi。两者都是优势物种。总植被覆盖率为100%。植物苔藓有三个亚层:最上层(高达3米)为雪梨生殖芽;中间的一个(1.0-1.5米)是它的叶子(有时相当多)和苏达戈(Solidago);较低的一层(最高可达0.5米)是雪莲幼苗,以及有下盖的千叶阿喀琉叶、毛蕊草、木贼草和木犀草幼苗。群落共有48种,每个样地有12 ~ 18种。这种群落在库尔斯克地区西北部很常见,分布在荒地、公路沿线和水库岸边。它们的出现是由于白毛茛渗透到驴的植物丛中(图8),以及白毛茛和黄毛茛在领土上同时传播(图9)。尽管土壤湿度和温度存在显著差异,但总体而言,黄毛茛变种和黄毛茛变种的生境相当相似(图10)。表8).在白棘棘变种的物种组成中,干生植物Onopordetalia acanthii目较少,而Epilobietea angustifolii纲种类较多(表9)。
Communities with Heracleum sosnowskyi Manden. in the Kursk Region
Classification of communities with Heracleum sosnovskyi in the Kursk Region (Table 1), based on 43 relevés, made by the author in 2014–2020 in some locations mainly in the western part of the study area (Fig. 1), is carried out according to Braun-Blanquet approach. The data are treated by IBIS 7.2 software package (Zverev, 2007). The names of the higher syntaxa follow to «Vegetation of Europe…» (Mucina et al., 2016). Synoptic tables include only species with constancy above I. Soil moisture, reaction, richness in mineral nitrogen, light, temperature and continentality are assessed using mean H. Ellenberg ecological indicator values (Ellenberg et al. 1992), hemeroby — with these of N. G. Ilminskikh ecological 9-point scale (Ilminskikh, 1993). Significant differences between pairs of syntaxa for each environmental factor are determined by the Mann-Whitney U-test in the PAST package (Hammer et al. 2001). 3 associations, 2 variants and 1 derivative community of 3 classes of vegetation are established. Ass. Chelidonio–Aceretum negundi L. Ishbirdina in L. Ishbirdina et al. 1989, var. Heracleum sosnowskyi (Table 2, Fig. 2). The association belongs to alliance Chelidonio–Acerion negundi L. Ishbirdina et A. Ishbirdin 1989, order Chelidonio–Robinietalia pseudoacaciae Jurco ex Hadač et Sofron 1980, class Robinietea Jurco ex Hadač et Sofron 1980. DS of the association are Acer negundo, Chelidonium majus, that of the variant is Heracleum sosnowskyi. Communities most often have three layers. The tree layer is dominated by Acer negundo with 7–20 m heigh and 50–90 % canopy density. The shrub layer (1–3 m, 1–50 %) is dominated by Acer negundo undergrowth, sometimes there are Padus avium, Populus alba, Prunus domestica, Sambucus nigra, S. racemosa, Ulmus glabra. The herb-dwarf shrub layer (height – 70–150 cm, plant cover – 50–100 %) is dominated by Heracleum sosnowskyi, mainly by its vegetative shoots. Generative shoots are found mainly in the most sunlit sites. There are 68 species in the association with 7–21 species per sample plot. The communities formed as a result of H. sosnowskyi penetration into phytocenoses of the var. typica ass. Chelidonio–Aceretum negundi are common in wastelands, along roads and banks of reservoirs, near abandoned houses in villages. There are slight differences in habitats of variants Heracleum sosnowskyi and typica (Fig. 3, Table 4): communities of the first one inhabit wetter soils, while these of the var. typica have the higher levels of temperature, continentality and hemerobiality, that is why there is a lot annuals and biennials, many of which are continental thermophilic species and belong to eu- and polyhemerobes (Lactuca serriola, Atriplex tatarica, Arctium tomentosumи др.). H. sosnowskyi exists even in heavily shaded areas. The species composition of communities of the var. Heracleum sosnowskyi is quite stable which is facilitated by the flow of seeds from surroundings and the capacity of germination of those seeds that did not germinate in the first year, as well as the ability of specimens to exist in a vegetative state for a long time under unfavorable conditions (Vinogradova et al., 2010; Panasenko, 2017). Ass. Urtico dioicae–Heracleetum sosnowskyi Panasenko et al. 2014 (Table. 5, rel. 1–17, Fig. 4). The association belongs to alliance Aegopodion podagrariae Tx. 1967 nom. conserv. propos., order Circaeo lutetianae–Stachyetalia sylvaticae Passarge 1967 nom. conserv. propos., class Epilobietea angustifolii Tx. et Preising ex von Rochow 1951. DS: Heracleum sosnowskyi, Urtica dioica. The total plant cover is 80–100 %. Communities have three sub-levels: the upper one (1.0–1.5 m) is of Heracleum sosnowskyi generative shoots; the mid one (1–1.5 m) is of its leaves; the lower one is of herbs Anthriscus sylvestris, Arctium tomentosum, Artemisia vulgaris, Ballota nigra, Cirsium arvense, Dactylis glomerata, Elytrigia repens, Galium aparine and Urtica dioica. There are 83 species in the association, with 9–29 species per sample plot. Such communities, formed as a result of Heracleum sosnowskyi invasion into phytocenoses of the class Epilobietea angustifolii, often occur in anthropogenic habitats. Derivative community Heracleum sosnowskyi [Agropyretalia intermedio–repentis] (Table. 5, rel. 18–25, Fig. 5). DS: Heracleum sosnowskyi. The total plant cover is 85–100 %. Communities have three sub-levels, just like in the previous syntaxon. However, in contrast to it, species of Artemisietea vulgaris Lohmeyer et al. in Tx. ex von Rochow 1951 prevail in the derivative community (Table. 6). Species of order Agropyretalia intermedio–repentis T. Müller et Görs 1969 are represented with high constancy. Such communities, formed as a result of Heracleum sosnowskyi invasion into phytocenoses of this order, occur along roads, in wastelands, on dry meadows. There are 68 species in the community coenoflora, with 7–30 species per sample plot. There are differences in habitats of this derivative community and the ass. Urtico dioicae–Heracleetum sosnowskyi (Fig. 6, Table 7). Communities of the association often inhabit wetter and eutrophic soils, while derivative ones are common in more sunlit and heated sites. Ass. Rudbeckio laciniatae–Solidaginetum canadensis Tüxen et Raabe ex Anioł-Kwiatkowska 1974, var. Heracleum sosnowskyi (Table. 5, rel. 26–31, Fig. 7). The association belongs to alliance Dauco-Melilotion Görs ex Rostański et Gutte 1971, order Onopordetalia acanthii Br.-Bl. et Tx. ex Klika et Hadač 1944, class Artemisietea vulgaris. DS of the association is Solidago сanadensis, this of the variant is Heracleum sosnowskyi. Both are dominating species. The total plant cover is 100 %. Phytocenoses have three sub-levels: the upper one (up to 3 m high) is of H. sosnowskyi generative shoots; the mid one (1.0–1.5 m) is of its leaves (sometimes quite numerous) and of Solidago сanadensis; the lower one (up to 0.5 m high) is of Heracleum sosnowskyi seedlings, as well as of Achillea millefolium, Carex hirta, Equisetum arvense and Poa angustifolia with lower cover. There are 48 species in the association, with 12–18 species per sample plot. Such communities common in the northwestern part of the Kursk region occur in wastelands, along roads and banks of reservoirs. They appeared as a result of Heracleum sosnowskyi penetration into phytocenoses of the ass. Rudbeckio laciniatae–Solidaginetum canadensis (Fig. 8), as well as with concurrent spread of both Heracleum sosnowskyi and Solidago сanadensis on the territory (Fig. 9). In spite of significant differences in soil moisture and temperature, in general, habitats of variants Solidago сanadensis and Heracleum sosnowskyi of the ass. Rudbeckio laciniatae–Solidaginetum canadensis are rather similar (Fig. 10, Table 8). There are fewer xeromesophytes of the order Onopordetalia acanthii and more species of the class Epilobietea angustifolii in the species composition of the var. Heracleum sosnowskyi (Table 9).
期刊介绍:
The scientific journal Rastitel''nost'' Rossii is included in the Scopus database. Publisher country is Russia. The main subject areas of published articles are Ecology, Evolution, Behavior and Systematics, Plant Science, Общая биология.