Moss occurrences in Yugyd Va National Park, Subpolar and Northern Urals, European North-East Russia

説明

データ レコード

この オカレンス（観察データと標本) リソース内のデータは、1 つまたは複数のデータ テーブルとして生物多様性データを共有するための標準化された形式であるダーウィン コア アーカイブ (DwC-A) として公開されています。 コア データ テーブルには、4,120 レコードが含まれています。

この IPT はデータをアーカイブし、データ リポジトリとして機能します。データとリソースのメタデータは、 ダウンロード セクションからダウンロードできます。 バージョン テーブルから公開可能な他のバージョンを閲覧でき、リソースに加えられた変更を知ることができます。

ダウンロード

DwC-A形式のリソース データまたは EML / RTF 形式のリソース メタデータの最新バージョンをダウンロード：

バージョン

次の表は、公にアクセス可能な公開バージョンのリソースのみ表示しています。

引用方法

研究者はこの研究内容を以下のように引用する必要があります。:

Zheleznova G, Shubina T, Degteva S, Rubtsov M, Chadin I (2020): Moss occurrences in Yugyd Va National Park, Subpolar and Northern Urals, European North-East Russia. v1.6. Institute of Biology of Komi Scientific Centre of the Ural Branch of the Russian Academy of Sciences. Dataset/Occurrence. http://ib.komisc.ru:8088/ipt/resource?r=mosses_occurrence_yugyd_va&v=1.6

権利

研究者は権利に関する下記ステートメントを尊重する必要があります。:

パブリッシャーとライセンス保持者権利者は Institute of Biology of Komi Scientific Centre of the Ural Branch of the Russian Academy of Sciences。 This work is licensed under a Creative Commons Attribution (CC-BY) 4.0 License.

GBIF登録

このリソースをはGBIF と登録されており GBIF UUID: 9192a5a8-5eba-4ec6-a336-797924214175が割り当てられています。   Participant Node Managers Committee によって承認されたデータ パブリッシャーとして GBIF に登録されているInstitute of Biology of Komi Scientific Centre of the Ural Branch of the Russian Academy of Sciences が、このリソースをパブリッシュしました。

キーワード

regional inventory; mosses; occurrence; Yugyd Va National Park; Subpolar Urals; Northern Urals; European North-East Russia; Komi Republic; Russian Federation; Occurrence

連絡先

地理的範囲

The length of Yugyd Va National Park is 280 km from North to South and 120 km from West to East. It is located on the western macroslopes of the Subpolar and Northern Urals. The Subpolar Urals are part of the Ural Mountains, and run from the headwaters of the Lyapin (Khulga) River in the north (65º40′N) to Telposiz Mountain in the south (64º0′N). The mountainous area covers about 32,000 km2. There are two main watersheds of the Subpolar Urals: Narodo-Itinsky in the east, with a length of more than 100 km, and Issledovatelsky in the west, with a length of more than 150 km. The northern continuation of the Issledovatelsky Range is the Rossomakha Ridge. Traces of glaciation are manifested in the large irregularities of these ridges. The slopes of the mountains are composed of stone placers. The Subpolar Urals are characterized by ridges with high altitudes and alpine landforms. The average height of the peaks is 1300-1400 m. The highest point of the Urals is located at Narodnaya Mountain (1,896 m). The Subpolar Urals have a pronounced asymmetry in their slopes: the eastern slopes of the Subpolar Urals gradually pass into the lowland wetlands of the West Siberian Lowland region, whereas the ridges of the western slopes end abruptly at the Pechora Plain. The Northern Urals begin at the northern foothills of Telposiz Mountain (1,617 m, 63°55′N) and stretch in a southward direction to Lyalinsky Kamen Mountain (851 m, 59°15'N). The Northern Urals are characterized by having a smooth topography with a maximum elevation of not more than 1,619 m above sea level (Telposiz Mountain). Along the western side of the Northern Urals there is a long strip of foothills, most of which only rise 200-300 m above sea level. The rivers in these regions mainly flow through narrow valley in which floodplains are often poorly expressed. The bottoms of the rivers are covered by pebbles and rocks. Large rounded boulders transported by ancient glaciers are also often found in the riverbeds. The vertical zonation of the Subpolar and Northern Urals consists of four belts: dark coniferous taiga, thin-wood forests with a predominance of larch, mountain tundra, and a cold goltsy desert belt. The vegetation of the mountainous dark coniferous taiga is formed mainly by Picea obovata and Betula pubescens mixed with Abies sibirica and Pinus sibirica. Submontane forests differ from the plain dark coniferous taiga by there being less waterlogging, with a predominance of green moss and grass vegetation types. As the altitude increases, the mountains’ forests are thinned and gradually pass into light forests. The upper boundary of the forests is formed by Larix sibirica, Abies sibirica, Pinus sibirica, and Betula pubescens. The cold goltsy desert belt in the Subpolar Urals begins at 300–400 m (Taskaev 2006, Chibilev 2011). The climate in this part of the Urals is strongly continental. The meridional location of the ridges has a significant effect on the climate by preventing the movement of moist air masses from west to east. The Subpolar and Northern Urals are distinguished from other parts of the Urals by the relatively abundant precipitation they receive (up to 1,500 mm per year). Most of the precipitation falls in the summer months, from June to August (40-50%). In winter, about 30-40% of the annual precipitation falls. The average monthly temperature of the coldest month (January) in these mountains ranges from -18 ºC to -20 ºC, while that of the warmest month (July) is +10 ºC. The duration of the summer period is 60-75 days (Ponomarev and Pystina 2009).

生物分類学的範囲

All mosses were identified to species. The coverage of the checklist spans the phylum Bryophyta. The highest number of records are from the Bryopsida (84.5%), followed by the Sphagnopsida (8.9%), Polytrichopsida (5.3%), Andreaeopsida (1%), and Tetraphidopsida (0.3%). The top ten families in terms of the number of species included comprise about 62% of the species. The top ten families in terms of the number of occurrences recorded comprise 77% of the occurrences. Of these two groups of top ten families, 60% were included in both groups.

時間的範囲

プロジェクトデータ

The aim of the project is to obtain new data about biodiversity of unexplored mountain regions of the Northern Urals and the Subpolar Urals. The obtained data will be used for soil and vegetation classification of different altitude zones of the Subpolar Urals and the Northern Urals. The rare plant species populations status will be estimated and the mechanisms of their stability will be determined. The data obtained during the project will be used for natural resources monitoring, decision supporting of protected area management. New data on the structural and functional traits of terrestrial ecosystems of different altitude and latitude zones of mountain landscapes will be used for solving the problems of biogeography and the history of biota formation in the Northern Urals and the Subpolar Urals. The biological diversity changes models under different climate change scenarios will be proposed.

プロジェクトに携わる要員:

収集方法

The authors contributing to the dataset used standard methods of mosses collection. The collecting localities were arbitrarily chosen in an attempt to include the largest number of different floristic associations and landscape forms in the samples. To achieve this purpose, a net of radial routes around each field base camp was planned. Short descriptions of plant communities were made in the localities of mosses collection. Moss samples were collected once and on each type of substrate. The results of this study were documented in the Herbarium (SYKO). In addition to the authors’ collections, the dataset includes information on moss occurrences obtained from sources in the published literature (Pole 1915, Zinserling 1935, Kildyushevskiy 1956, Gorchakovskii 1958, Kuvaev 1970, Dyachenko and Fomicheva 1986, Dyachenko 1997). More than 92% of the occurrence records were based on preserved samples from the Herbarium (SYKO). Some records (412) from locations adjacent to the border of the National Park were also included in the dataset.

Method step description:

1. On each herbarium label, the following fields were filled out: “Scientific name”, “Locality” (with geographic coordinates), “Habitat”, “Substrate”, “Collector name”, “Determined by” (identification), “Collection date”, and “Catalogue Number”. For the data obtained from the literature, the descriptions given by the author(s) were converted into these herbarium label fields when possible. The dataset fields’ names were chosen according to Darwin Core (Wieczorek et al. 2012) and include the following: «occurrenceID», «cаtаlogNumber», «associatedReferences», «basisOfRecord», «kingdom», «phylum», «class», «family», «genus», «scientificName», «specificEpithet», «scientificNameAuthorship», «country», «countryCode», «recordedBy», «day», «month», «year», «locality», «identifiedBy», «decimalLatitude», «decimalLongitude», «coordinatePrecision», «coordinateUncertaintyInMeters», «georeferencedBy», and «geodeticDatum». References to the published literature from which data were obtained for the checklist compilation are presented in the “citations” section of the metadata. The herbarium label data were taken from the moss collection of the Herbarium (SYKO). All occurrence records were merged into one Microsoft Excel worksheet. The species names given were determined according to the “Check-list of mosses of East Europe and North Asia” (Ignatov et al. 2006). The unique values from the “Species” field were used as a preliminary Yugyd Va National Park mosses checklist. The preliminary checklist was verified on the “taxonomic name resolution service” (Boyle et al. 2013) with the help of the “taxize” package in the R environment (Chamberlain and Szocs 2013). In most cases, georeferencing was performed using paper maps of different scales. The maps were in the Kavrayskiy projection and SK-42 reference system. Maps with a 1:500000 scale were used for obtaining coordinates with 1-minute precision (3,903 occurrences). Maps with a scale of 1:100000 were used for obtaining 1-second-precision coordinates (269 occurrences). A remaining 22 occurrences were left ungeoreferenced because of the ambiguity of the locality description. All coordinates were transformed in the WGS 84 reference system with QGIS software. The coordinate uncertainty in meters for each occurrence was calculated with the Georeferencing Calculator (Wieczorek and Wieczorek 2015).

コレクションデータ

書誌情報の引用

1. Pole R.R. 1915. Materialy dlya poznaniya rastitelnosti severnoy Rossii. K flore mhov severnoy Rossii [Materials for knowledge of the vegetation of Northern Russia. To the flora of mosses of the North of Russia] — In: Proceedings of the Imperial Botanic garden of Peter the Great. T. 33. Vol. 1. Petrograd. 148 p. (in Russ.). Tsinzerling Yu. D. 1935. Ocherk rastitelnosti massiva Sabli [The vegetation of the array of the ridge Sablya] — In: Ural. Pripolyarnye rayony. Tr. Lednikovykh ekspeditsiy. Vyp.4. Leningrad. P. 75–86. (in Russ.).
2. Kildyushevskiy I. D. 1956. K flore mhov Pripolyarnogo Urala [To the moss flora of the Polar Urals] — In: Tr. Bot. in-ta im. V.L. Komarova AN SSSR. Ser 2. Sporovye rasteniya. V. 11. P. 313–332. (in Russ.).
3. Gorchakovskiy P. L. 1958. Rastitelnost khrebta Sabli na Pripoljarnom Urale [The vegetation of the ridge Sablya, Subpolar Urals] — In: Rastitelnost Kraynego Severa SSSR i ee osvoenie. Moscow-Leningrad. Vol. 3. P. 95–127. (in Russ.).
4. Kuvaev V. B. 1970. Lishayniki i mkhi Pripolyarnogo Urala i prilegayushchikh ravnin [Lichens and mosses of the polar Urals and adjacent plains] — In: Sporovye rasteniya Urala. Tr. In-ta ekol. rast. i zhivot. UrF AN SSSR. Vyp. 70. Sverdlovsk. P. 61–92. (in Russ.).
5. Dyachenko A. P. 1997. Flora listostebelnykh mkhov Urala. Chast 1: Istoriya izucheniya. Konspekt. Taksonomicheskiy analiz [Flora of mosses of the Urals. Part 1: History of study. Abstract. Taxonomic analysis]. Ekaterinburg. 264 p. (in Russ.).
6. Dyachenko A. P., Fomicheva L. N. 1986. K flore listostebelnykh mkhov naibolee poseshchaemykh territoriy khrebta Sablinskiy [Flora of mosses of the most visited areas of the Sablinskiy ridge] — In: Gornye ekosistemy Urala i problemy ratsionalnogo prirodopolzovaniya. Sverdlovsk. 18 p. (in Russ.).
7. Ignatov M.S., Afonina O.M., Ignatova E.A. et al. 2006. Check-list of mosses of East Europe and North Asia. Arctoa. 15: 1–130. doi 10.15298/arctoa.15.01
8. Krasnaya kniga Respubliki Komi [Red Data Book of the Komi Republic]. 2009. Syktyvkar 791 p. https://ib.komisc.ru/add/rb/
9. Boyle, B. et al. 2013. The taxonomic name resolution service: an online tool for automated standardization of plant names. BMC Bioinformatics 14:16. doi:10.1186/1471-2105-14-16 Scott Chamberlain and Eduard Szocs (2013). taxize - taxonomic search and retrieval in R. F1000Research, 2:191. http://f1000research.com/articles/2-191/v2
10. Wieczorek J., Bloom D., Guralnick R., Blum S., Doring M., De Giovanni R., Robertson T., Vieglais D. 2012. Darwin Core: An Evolving Community-developed Biodiversity Data Standard. PLoS ONE. 7 (1). doi:10.1371/journal.pone.0029715. doi:10.1371/journal.pone.0029715
11. Zheleznova G, Shubina T, Chadin I (2018): Mosses checklist of Yugyd Va National Park, Subpolar and Northern Urals, European North-East Russia. v1.4. Institute of Biology of Komi Scientific Centre of the Ural Branch of the Russian Academy of Sciences. Dataset/Checklist. http://ib.komisc.ru:8088/ipt/resource?r=mosses_checkst_of_yugyd_va_national_park&v=1.4

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