Труды сотрудников ИЛ им. В.Н. Сукачева СО РАН

[Text] / S. M. Gorozhankina, V. D. Konstantinov // Russ. J. Ecol. - 1999. - Vol. 30, Is. 4. - P248-254. - Cited References: 29 . - 7. - ISSN 1067-4136РУБ Ecology

Аннотация: Some aspects of the ecology of plants widely distributed in the middle taiga of the left-bank Yenisei region in hydromorphic habitats-swamped forests and bogs-are discussed. Their dependence on two basic factors, soil acidity and hydrologic regime, was analyzed. Plant species were arranged in ecological-cenotic groups by the method of two-dimensional ordination with respect to these factors and comparatively characterized by the criterion of ecological plasticity.

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Держатели документа:
Russian Acad Sci, Siberian Div, Sukachev Inst Forestry, Krasnoyarsk 660036, Russia

Доп.точки доступа:
Gorozhankina, S.M.; Konstantinov, V.D.

[Text] / O. A. Zyryanova [et al.] // Contemp. Probl. Ecol. - 2008. - Vol. 1, Is. 1. - P22-28, DOI 10.1134/S1995425508010037. - Cited References: 79. - The work is financially supported by Integration projects of SB RAS No 5.17, 5.18, 11.15, grants of Russian Foundation of Basic Research 06-04-48052 and 06-04-81026. . - 7. - ISSN 1995-4255РУБ Ecology

Аннотация: Being of global ecological significance, boreal forests of Siberia located at the high latitudes of Northern Eurasia serve as a unique source of genetic, species, and ecosystem diversity. Previously conducted research revealed a wide range of scientific problems regarding the intraspecific diversity of trees, estimation of the structure and current state of forest ecosystems, as well as their ordination and classification. The use of modem information technologies (databases, species diversity indices, GIS) can promote the knowledge on Siberian boreal forests to a higher level.

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Держатели документа:
[Zyryanova, O. A.
Milyutin, L. I.
Muratova, E. N.
Ryzhkova, V. A.
Larionova, A. Ya.
Sedel'nikova, T. S.
Korets, M. A.
Mikhailova, I. A.] RAS, Siberian Branch, Inst Forest, Krasnoyarsk 660036, Russia

Доп.точки доступа:
Zyryanova, O.A.; Milyutin, L.I.; Muratova, E.N.; Ryzhkova, V.A.; Larionova, A.Y.; Sedel'nikova, T.S.; Korets, M.A.; Mikhailova, I.A.

[Text] / N. M. TCHEBAKOVA [et al.] // J. Biogeogr. - 1993. - Vol. 20, Is. 2. - P129-144, DOI 10.2307/2845667. - Cited References: 74 . - 16. - ISSN 0305-0270РУБ Ecology + Geography, Physical

Аннотация: A global vegetation model based on the climatological approach of Budyko is developed. The major vegetation zones of the world are predicted by a two-dimensional ordination of a Dryness Index and Potential Evaporation, which is derived from radiation balance. Mean temperature of the warmest month is also used to separate the Ice/Polar Desert, Tundra, and Taiga zones. Predictions of vegetation distributions are made using a global climate database interpolated to a 0.50 by 0.50 terrestrial grid. The overall impression from examining the resulting global vegetation map is that the modified Budyko model predicts the location and distribution of the world's vegetation fairly well. Comparison between model predictions and Olson's actual vegetation map were based on Kappa statistics and indicate good agreement for Ice/Polar Desert, Tundra, Taiga, and Desert (even though we predict too much Desert). Agreement with Olson's map was fair for predicting the specific location of Tropical Rain Forest and Tropical Savannas, and was good for predicting their general location at a larger scale. Agreement between Olson's map and model predictions were poor for Steppe, Temperate Forest, Tropical Seasonal Forest, and Xerophytic Shrubs, although the predictions for Temperate Forest and Tropical Seasonal Forest improved to fair at a larger scale for judging agreement. Agreement with the baseline map of Olson was poor for Steppe and Xerophytic Shrubs at all scales of comparison. Based on Kappa statistics, overall agreement between model predictions and Olson's map is between fair and good, depending on the scale of comparison. The model performed well in comparison to other global vegetation models. Apparently the calculation of radiation balance and the resulting Dryness Index and Potential Evaporation provides important information for predicting the distribution of the major vegetation zones of the world.

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Держатели документа:
ACAD SCI,INST FOREST,ACADEMGORODOK,660036 KRASNOYARSK,RUSSIA
USDA,INTERMT RES STN,FOREST SERV,MOSCOW,ID 83843
NATL INST PUBL HLTH & ENVIRONM PROTECT,DEPT GLOBAL CHANGE,3720 BILTHOVEN,NETHERLANDS
INT INST APPL SYST ANAL,A-2361 LAXENBURG,AUSTRIA

Доп.точки доступа:
TCHEBAKOVA, N.M.; MONSERUD, R.A.; LEEMANS, R...; GOLOVANOV, S...

[Text] / R. A. Monserud, N. M. Tchebakova // Can. J. For. Res.-Rev. Can. Rech. For. - 1996. - Vol. 26, Is. 6. - P1055-1068, DOI 10.1139/x26-117. - Cited References: 49 . - 14. - ISSN 0045-5067РУБ Forestry

Аннотация: A mountain vegetation model driven by regional climatic parameters was developed for predicting the geographic distribution of the numerous ecosystems of the Sayan Mountain system in southern Siberia. Meteorological data are drawn from normal records of monthly means. Four climatic variables were interpolated to a 10' by 10' grid: temperature, precipitation, vapor pressure, and cloudiness. In addition, albedo was derived by 100-m elevation classes for both windward and leeward slopes as a function of the general type of vegetation surface and the dates of snow occurrence. Ecosystems were classified using a two-dimensional climatic ordination. The first dimension was growing degree-days above a 5 degrees C threshold, and the second was Budyko's dryness index, which is based on annual radiation balance and annual precipitation. The patterns: of predicted vegetation corresponded rather well to observed mapped vegetation. Overall kappa statistics indicated agreement with observed vegetation that varied from fair at the finest resolution (10' by 10' cells) to good at intermediate resolution (30' by 30' cells and 1 degrees by 1 degrees cells) to very good at the coarsest resolution (2 degrees by 2 degrees cells). Focusing on individual vegetation classes, agreement was good to very good for each vegetation class at intermediate resolutions and very good to excellent for each vegetation class at the 2 degrees by 2 degrees resolution. Thus, the general location, pattern, and overall distribution of these mountain ecosystems was accurately predicted. This approach for predicting the spatial distribution of biomes was successfully applied at both the global and subcontinental scale. The successful extension of Budyko's radiation balance approach to mountainous terrain on a finer resolution regional scale indicates the generality of the approach.

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Держатели документа:
RUSSIAN ACAD SCI,FOREST INST,KRASNOYARSK 660036,RUSSIA

Доп.точки доступа:
Monserud, R.A.; Tchebakova, N.M.

/ L. V. Krivobokov, D. I. Nazimova // Geography and Natural Resources. - 2011. - Vol. 32, Is. 1. - P40-47, DOI 10.1134/S1875372811010070 . - ISSN 1875-3728
Аннотация: An ecologo-phytocenotic classification of forest types has been worked out for the mountainous areas of the Western Transbaikalia. Using the floristic and ecologo-geographical criteria and the DCA ordination method, we identified seven groups of forest types belonging to two altitudinal-belt complexes. The resulting classification refines the existing understanding of the phytocenotic structure of forest cover under sharply continental climate conditions in the contact zone with island steppes of the Transbaikalia and serves the vegetation cover monitoring and modeling purposes. В© 2011 Pleiades Publishing, Inc.

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Держатели документа:
Institute of General and Experimental Biology, Siberian Branch, Russian Academy of Sciences, Ulan-Ude, Russian Federation
Institute of Forest, Siberian Branch, Russian Academy of Sciences, Krasnoyarsk, Russian Federation

Доп.точки доступа:
Krivobokov, L.V.; Nazimova, D.I.

/ D. I. Nazimova, V. G. Tsaregorodtsev, N. M. Andreyeva // Geography and Natural Resources. - 2010. - Vol. 31, Is. 2. - P124-131, DOI 10.1016/j.gnr.2010.06.006 . - ISSN 1875-3728
Аннотация: Data from the " Biome" information system were used to construct an ordination of zonal categories of vegetation cover in southern Siberia along the axes of heat supply and continentality. The changes of climate that occurred from the end of the 1960. s to 2007 are estimated. It is shown that they can lead to transformation of the composition of potential forest vegetation in a number of regions. We discuss the forecasted and observed variants of long-term successions in different sectoral-zonal classes of subtaiga and forest-steppe, including the risk of a reduction in the areas of separate forest-forming species. В© 2010.

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Держатели документа:
Institute of Forest SB RAS, Krasnoyarsk, Russian Federation

Доп.точки доступа:
Nazimova, D.I.; Tsaregorodtsev, V.G.; Andreyeva, N.M.

/ D. I. Nazimova, N. P. Polikarpov // Silva Fennica. - 1996. - Vol. 30, Is. 2-3. - P201-208 . - ISSN 0037-5330
Аннотация: A system of zonality in Siberia has been formed under the control of continentality, which provides the heat and humidity regimes of the forest provinces. Three sectors of continentality and four to six boreal subzones form a framework for the systematisation of the different features of land cover in Siberia. Their climatic ordination provides the fundamental basis for the principal potential forest types (composition, productivity) forecasting the current climate. These are useful in predicting the future transformations and successions under global changes.

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Держатели документа:
V. N. Sukhachev Institute of Forest, Siberian Branch, Russian Academy of Sciences, Akademgorodok, Krasnoyarsk 660036, Russian Federation

Доп.точки доступа:
Nazimova, D.I.; Polikarpov, N.P.

/ R. A. Monserud [et al.] // Silva Fennica. - 1996. - Vol. 30, Is. 2-3. - P185-200 . - ISSN 0037-5330
Аннотация: An equilibrium model driven by climatic parameters, the Siberian Vegetation Model, was used to estimate changes in the phytomass of Siberian vegetation under climate change scenarios (CO2 doubling) from four general circulation models (GCM's) of the atmosphere. Ecosystems were classified using a three-dimensional climatic ordination of growing degree days (above a 5В°C threshold), Budyko's dryness index (based on radiation balance and annual precipitation), and Conrad's continentality index. Phytomass density was estimated using published data of Bazilevich covering all vegetation zones in Siberia. Under current climate, total phytomass of Siberia is estimated to be 74.1 В± 2.0 Pg (Petagram = 1015 g). Note that this estimate is based on the current forested percentage in each vegetation class compiled from forest inventory data. Moderate warming associated with the GISS (Goddard Institute for Space Studies) and OSU (Oregon State Univ.) projections resulted in a 23-26 % increase in phytomass (to 91.3 В± 2.1 Pg and 93.6 В± 2.4 Pg, respectively), primarily due to an increase in the productive Southern Taiga and Subtaiga classes. Greater warming associated with the GFDL (General Fluid Dynamics Laboratory) and UKMO (United Kingdom Meteorological Office) projections resulted in a small 3-7 % increase in phytomass (to 76.6 В± 1.3 Pg and 79.6 В± 1.2 Pg, respectively). A major component of predicted changes using GFDL and UKMO is the introduction of a vast Temperate Forest-Steppe class covering nearly 40 % of the area of Siberia, at the expense of Taiga; with current climate, this vegetation class is nearly non-existent in Siberia. In addition, Subboreal Forest-Steppe phytomass doubles with all GCM predictions. In all four climate change scenarios, the predicted phytomass stock of all colder, northern classes is reduced considerably (viz., Tundra, Forest-Tundra, Northern Taiga, and Middle Taiga). Phytomass in Subtaiga increases greatly with all scenarios, from a doubling with GFDL to quadrupling with OSU and GISS. Overall, phytomass of the Taiga biome (Northern, Middle, Southern, and Subtaiga) increased 15 % in the moderate OSU and GISS scenarios and decreased by a third in the warmer UKMO and GFDL projections. In addition, a sensitivity analysis found that the percentage of a vegetation class that is forested is a major factor determining phytomass distribution. From 25 to 50 % more phytomass is predicted under climate change if the forested proportion corresponding to potential rather than current vegetation is assumed.

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Держатели документа:
Intermountain Research Station, USDA Forest Service, 1221 S. Main St., Moscow, ID 83843, United States
Forest Institute, Russian Academy of Sciences, Akademgorodok, 660036 Krasnoyarsk, Russian Federation
Department of Civil Engineering, Oregon State University, Corvallis, OR 97333, United States
Department of Geography, Moscow State University, 119899 Moscow, Russian Federation

Доп.точки доступа:
Monserud, R.A.; Tchebakova, N.M.; Kolchugina, T.P.; Denissenko, O.V.

[Text] / S. M. GOROZHANKINA // SOVIET JOURNAL OF ECOLOGY. - 1990. - Vol. 21, Is. 3. - P119-126. - Cited References: 0 . - 8. - ISSN 0096-7807РУБ Ecology

Аннотация: The ecological-genetic laws governing bog formation in the typical taiga landscape of Western Siberia are examined. A qualitative model is presented of the contemporary structure of the biogeocenotic cover by means of a ranked topo-ecological ordination of the biogeocenoses according to progressive soil hydromorphism. A retrospective-evolutionary analysis of this model is carried out based on radiocarbon dating of the peat deposits. It is shown that the contemporary topo-ecological order of marshiness fixes the chronological succession of the stage conditions of progressive hydromorphism and can be useful in an evolutionary-historical reconstruction of the bog formation process.

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Доп.точки доступа:
GOROZHANKINA, S.M.

[Текст] / E. N. MURATOVA, B. A. KRAVTSOV, E. V. LYUBSHINA // IZVESTIYA AKADEMII NAUK SSSR SERIYA BIOLOGICHESKAYA. - 1988. - Is. 4. - С. 594-601. - Cited References: 33 . - 8. - ISSN 0002-3329РУБ Biology


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Доп.точки доступа:
MURATOVA, E.N.; KRAVTSOV, B.A.; LYUBSHINA, E.V.

[Текст] / B. A. KRAVTSOV, L. I. MILYUTIN // Zhurnal Obshchei Biol. - 1985. - Vol. 46, Is. 4. - С. 557-564. - Cited References: 14 . - 8. - ISSN 0044-4596РУБ Biology


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Доп.точки доступа:
KRAVTSOV, B.A.; MILYUTIN, L.I.

/ L. Krivobokov, A. Zverev, L. Mukhortova [et al.] ; ed.: E. V. Banaev [et al.] // INTERNATIONAL CONFERENCES PLANT DIVERSITY: STATUS, TRENDS, CONSERVATION : E D P SCIENCES, 2020. - Vol. 24: International Conference on Plant Diversity - Status, Trends, (SEP 30-OCT 03, 2020, Novosibirsk, RUSSIA). - Ст. 00044. - (BIO Web of Conferences), DOI 10.1051/bioconf/20202400044. - Cited References:12. - The research was carried out within the framework of the State Assignments of Sukachev Institute of Forest SB RAS "Biodiversity of primary coniferous and derived forest ecosystems" (state registration number: AAAA-A17-117101820003-0) and "The dynamics of the Siberian forests in a changing climate: monitoring the vital state, productivity and area of the main forest-forming species of woody plants "(state registration number: AAAA-A17-117101940016-3), as well as with partial financial support of Russian Foundation for Basic Research (grant No. 18-04-01068-a). . -
Аннотация: The main types of forest plant communities in the southern part of the Central Siberian Plateau (the lower reaches of the Podkamennaya Tunguska River Basin) were separated. Basic ecological gradients crucial for formation and functioning of these types of plant communities were identified using the methods of ordination.

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Держатели документа:
RAS, SB, Sukachev Inst Forest, 50-28 Akademgorodok, Krasnoyarsk 660036, Russia.
Tomsk State Univ, 36 Lenin St, Tomsk 634050, Russia.
Univ Regensburg, 31 Univ Str, D-93040 Regensburg, Germany.

Доп.точки доступа:
Krivobokov, Leonid; Zverev, Andrej; Mukhortova, Liudmila; Sergeeva, Oksana; Rosbakh, Sergej; Banaev, E.V. \ed.\; Tomoshevich, M.A. \ed.\; Zaytseva, Y.G. \ed.\; Russian Foundation for Basic ResearchRussian Foundation for Basic Research (RFBR) [AAAA-A17-117101940016-3, AAAA-A17-117101820003-0, 18-04-01068-a]

/ V. P. Vetrova, A. P. Barchenkov, N. V. Sinelnikova // Vestn. Tomsk. Gos. Univ. Biol. - 2021. - Is. 53. - С. 47-67, DOI 10.17223/19988591/53/3. - Cited References:38 . - ISSN 1998-8591. - ISSN 2311-2077РУБ Biology + Ecology

Аннотация: Geometric morphometric analysis of shape variation in the cone scales of two closely related larch species, Larix dahurica Laws. (=Larix gmelinii (Rupr.) Rupr) and L. cajanderi Mayr, was carried out. The data on the taxonomy and distribution of L. dahurica and L. cajanderi are contradictory. The taxonomic status of L. cajanderi has been confirmed by the genetic and morphological studies performed in Russia and based on considerable evidence, but the species has not been recognized internationally, being considered as a synonym of Larix gmelinii var. gmelinii. In the systematics of larch, morphological characters of the generative organs are mainly used as diagnostic markers, among the most important being the shape variation of the cone scales. The aim of this study was to test geometric morphometrics as a tool for analyzing differentiation of L. dahurica and L. cajanderi in the shape of their cone scales. Characterization of shape variations in cone scales using geometric morphometric methods consists in digitizing points along an outline of scales followed by analysis of partial warps, describing individual differences in coordinates of the outline points. We studied the populations of L. dahurica from Evenkia and the Trans-Baikal region and six L. cajanderi populations from Yakutia and Magadan Oblast. In each population, we analyzed samples of 100-150 cones collected from 20-30 trees. Scales taken from the middle part of the cones were scanned using an Epson Perfection V500 Photo. On the scanned images, outline points were placed with a TPSDig program (Rolf, 2010), using angular algorithm (Oreshkova et al., 2015). The data were processed and analyzed using Integrated Morphometrics Programs (IMP) software (http://www.canisius.edu/similar to sheets/morphsoft.html, Sheets, 2001), following the guidelines on geometric morphometrics in biology (Pavlinov, Mikeshina, 2002; Zelditch et al., 2004). Initial coordinates of the scale landmarks were aligned with the mean structure for L. dahurica and L. cajanderi cone scales using Procrustes superimposition in the CoordGen6 program. PCA based on covariances of partial warp scores was applied to reveal directions of variation in the shape of the cone scales. The relative deformations of the cone scales (PCA scores) were used as shape variables for statistical comparisons of these two larch species with canonical discriminant analysis. Morphotypes of the cone scales were distinguished in L. dahurica populations by pairwise comparison of samples from trees in the TwoGroup6h program using Bootstrap resampling-based Goodall's F-test (Sheets, 2001). Samples from the trees in which the cone scales differed significantly (p 0.01) were considered to belong to different morphotypes. Morphotypes distinguished in L. dahurica populations were compared with the morphotypes that we had previously determined in L. cajanderi populations. The composition and the frequency of occurrence of morphotypes were used to determine phenotypic distances between populations (Zhivotovskii, 1991). Multidimensional scaling matrix of the phenotypic distances was applied for ordination of larch populations. In this research, we revealed differentiation of L. dahurica and L. cajanderi using geometric morphometric analysis of the shape variation of cone scales. The results of PCA of partial warp scores exposed four principal components, which account for 90% of total explained variance in the shape of the cone scales in the two larch species. Graphical representations of these shape transformations in the vector form characterized directions of shape variability in scales corresponding to the maximum and minimum values of four principal components (See Fig. 2). PCA-ordination of the larch populations revealed some difference in the shape variation of the cone scales in L. dahurica and L. cajanderi (See Fig. 3). The results of canonical discriminant analysis of relative deformations of scales showed differentiation of the populations of the two larch species (See Fig. 4). Eleven morphotypes were identified in L. dahurica cones from Evenkia and nine morphotypes in the Ingoda population, three of the morphotypes being common for both populations (See Fig. 5). The shape of L. dahurica cone scales varied from spatulate to oval and their apical margins from weakly sinuate to distinctly sinuate. The Trans-Baikal population was dominated by scales with obtuse (truncate) and rounded apexes. The obtained morphotypes were compared with 25 cone scale morphotypes previously distinguished in the Yakut and the Magadan L. cajanderi populations (See Fig. 3). Four similar morphotypes of cone scales were revealed in the North-Yeniseisk population of L. dahurica and the Yakut populations of L. cajanderi. The differences between them in the populations of the two larch species were nonsignificant (p 0.01). All morphotypes of cone scales from the Ingoda population of L. dahurica differed significantly from L. cajanderi cone scale morphotypes. The results of multidimensional scaling phenotypic distance matrix calculated based on the similarity of morphotypes of L. dahurica and L. cajanderi populations were consistent with the results of their differentiation based on relative deformations of scales obtained using canonical discriminant analysis (See Fig. 4 and Fig. 7). In spite of the differences in the shape of the cone scales between the North-Yeniseisk and the Trans-Baikal populations of L. dahurica, they both differed from L. cajanderi populations. Thus, phenotypic analysis confirmed differentiation of these two larch species. Despite the similarities between a number of morphotypes, the Yakut L. cajanderi populations were differentiated from L. dahurica populations. Significant differences were noted between intraspecific groups: between L. cajanderi populations from Okhotsk-Kolyma Upland and Yakutia and between L. dahurica populations from Evenkia and the Trans-Baikal region (See Fig. 4). The similarities between species and intraspecific differences may be attributed to the ongoing processes of hybridization and species formation in the region where the ranges of the larches overlap with the ranges of L. czekanowskii Szafer and L. dahuricax L. cajanderi hybrids. Geometric morphometrics can be used as an effective tool for analyzing differentiation of L. dahurica and L. cajanderi in the shape of their cone scales. The paper contains 7 Figures, 1 Table and 38 References.

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Держатели документа:
Russian Acad Sci, Lab Plant Ecol, Kamchatka Branch Pacific Geog Inst, Far Eastern Branch, 19-A Rybakov Ave, Petropavlovsk Kamchatski 683024, Russia.
Russian Acad Sci, Lab Forest Genet & Breeding, VN Sukachev Inst Forest, Siberian Branch, 50-28 Academgorodok, Krasnoyarsk 660036, Russia.
Siberian Fed Univ, Lab Biogeochem Ecosyst, 79 Svobodny Ave, Krasnoyarsk 660041, Russia.
Russian Acad Sci, Inst Biol Problems North, Lab Bot, Far Eastern Branch, 18 Portovaya Str, Magadan 685000, Russia.

Доп.точки доступа:
Vetrova, Valentina P.; Barchenkov, Alexey P.; Sinelnikova, Nadezhda, V