Your search keyword '"Drobyshev I"' showing total 5 results

1. Inter-annual and decadal changes in teleconnections drive continental-scale synchronization of tree reproduction.

Author

Ascoli D, Vacchiano G, Turco M, Conedera M, Drobyshev I, Maringer J, Motta R, and Hacket-Pain A

Subjects

Conservation of Natural Resources methods, Conservation of Natural Resources trends, Ecosystem, Fagus growth & development, Picea growth & development, Pollination, Reproduction, Seeds growth & development, Trees classification, Climate, Climate Change, Seasons, Seed Dispersal, Trees growth & development

Abstract

Climate teleconnections drive highly variable and synchronous seed production (masting) over large scales. Disentangling the effect of high-frequency (inter-annual variation) from low-frequency (decadal trends) components of climate oscillations will improve our understanding of masting as an ecosystem process. Using century-long observations on masting (the MASTREE database) and data on the Northern Atlantic Oscillation (NAO), we show that in the last 60 years both high-frequency summer and spring NAO, and low-frequency winter NAO components are highly correlated to continent-wide masting in European beech and Norway spruce. Relationships are weaker (non-stationary) in the early twentieth century. This finding improves our understanding on how climate variation affects large-scale synchronization of tree masting. Moreover, it supports the connection between proximate and ultimate causes of masting: indeed, large-scale features of atmospheric circulation coherently drive cues and resources for masting, as well as its evolutionary drivers, such as pollination efficiency, abundance of seed dispersers, and natural disturbance regimes.

Published

2017

2. Dendroclimatology in Fennoscandia -- from past accomplishments to future potential.

Author

Linderholm, H. W., Björklund, J. A., Seftigen, K., Gunnarson, B. E., Grudd, H., Jeong, J.-H., Drobyshev, I., and Liu, Y.

Subjects

DENDROCHRONOLOGY, TAIGAS, ATMOSPHERIC circulation, CLIMATE change

Abstract

Fennoscandia has a strong tradition in dendrochronology, and its large tracts of boreal forest make the region well suited for the development of tree-ring chronologies that extend back several thousands of years. Two of the world's longest continuous (most tree-ring chronologies are annually resolved) tree-ring width chronologies are found in northern Fennoscandia, with records from Torneträsk and Finnish Lapland covering the last ca. 7500 yr. In addition, several chronologies between coastal Norway and the interior of Finland extend back several centuries. Tree-ring data from Fennoscandia have provided important information on regional climate variability during the mid to late Holocene and have played major roles in the reconstruction of hemispheric and global temperatures. Tree-ring data from the region have also been used to reconstruct large-scale atmospheric circulation patterns, regional precipitation and drought. Such information is imperative when trying to reach better understanding of natural climate change and variability and its forcing mechanisms, and placing recent climate change within a long-term context. [ABSTRACT FROM AUTHOR]

Published

2010

3. Marginal imprint of human land use upon fire history in a mire-dominated boreal landscape of the Veps Highland, North-West Russia.

Author

Drobyshev, I., Ryzhkova, N., Niklasson, M., Zhukov, A., Mullonen, I., Pinto, G., and Kryshen', A.

Subjects

FIRE management, LAND use, UPLANDS, NATURE parks, LANDSCAPES, DROUGHTS, TWENTIETH century

Abstract

• Veps Highland deviates from other Nordic fire history reconstructions with its period of increased fire activity being observed exclusively during the 1700s. • The land-use history of the area did not appear to have an effect on the historical fire dynamics. • The fire regime of the Veps Highland remained largely natural until the onset of the 20th century. Dendrochronological reconstructions inform us about historical climate-fire-human interactions, providing a means to calibrate projections of future fire hazard. Most of these reconstructions, however, have been developed in landscapes with a considerable proportion of xeric sites that could potentially inflate our estimates of the historic levels of fire activity. We provide a 420-year long reconstruction of fires in a mire-dominated landscape of the Veps Nature Park, North-West Russia. The area has mostly escaped large-scale forestry operations in the past and is an example of pristine mid-boreal vegetation with a high (approximately 30% for the area studied) proportion of waterlogged areas with ombrotropic mires. The historical fire cycle was 91.4 years (90% confidence intervals, CI 66.2–137.6 years) over the 1580–1720 period, decreasing to 35.9 (CI 28.1–47.6 years) between 1730 and 1770, and then increasing again to 122.7 years (CI 91.0–178.0 years) over the 1780–2000 period. Early season fires dominated over late season fires during the reconstruction period. We documented a higher fire activity period between 1730 and 1780, resulting from the increase in early season fires. This period coincided with one of the largest multi-decadal declines in the reconstructed spring precipitation since 1600 CE, although we found no significant relationship between fire and precipitation over the whole reconstructed period. The nine largest fire years were associated with negative summer precipitation and positive summer temperature anomalies over the study region. Land-use history of the area did not appear to have an effect on historical fire dynamics. Modern (1996–2016) fire records indicate a regional fire cycle of ∼ 1300 years, featuring a pronounced pattern with early (April–May) and late (July–September) season fires. The uniform fire cycle in the area since 1780, occurrence of nine largest fire years during years with spring-summer droughts, and low ignition frequencies over the last 420 years (0.005 to 0.037 ignitions per year and km2) suggest that the fire regime of the Veps Highland remained largely natural until the onset of the 20th century. [ABSTRACT FROM AUTHOR]

Published

2022

4. Decline in the strength of genetic controls on aspen environmental responses from seasonal to century‐long phenomena.

Author

Drobyshev, I., Picq, S., Ganivet, E., Tremblay, F., and Bergeron, Y.

Subjects

ASPEN (Trees), PLANT phenology, POPULUS tremuloides, CLIMATE sensitivity, CLIMATE change, INSECT growth

Abstract

Understanding intra‐specific variation in climate sensitivity could improve the prediction of tree responses to climate change. We attempted to identify the degree of genetic control of tree phenology and growth of trembling aspen (Populus tremuloides Mchx.) in a natural stand of this species in northwestern Quebec. We mapped and genotyped 556 aspen trees growing within the plot, using seven nuclear microsatellite loci for clone identification. We selected 13 clones (n of trees per clone >5, in total 350 trees) and evaluated the explanatory power of clone identity in (a) variability of spring leaf phenology and (b) short‐ and long‐term growth responses. The clone's identity explained 43% of the variability in spring leaf phenology, between 18% and 20% of variability in response to monthly climate variables significantly affecting growth, between 8% and 26% of growth response to insect outbreaks, and 12% in the long‐term growth rates. Strong clonal control of aspen phenology and moderate control of growth responses to monthly weather do not result in an equally large impact on long‐term growth rates. The result suggests an important role of environmental extremes and within community interactions as factors averaging aspen growth performance at the stand level. [ABSTRACT FROM AUTHOR]

Published

2019

5. Jet stream position explains regional anomalies in European beech forest productivity and tree growth

Author

Dorado-Liñán, Isabel, Ayarzagüena, Blanca, Babst, Flurin, Xu, Guobao, Gil, Luis, Battipaglia, Giovanna, Buras, Allan, Čada, Vojtěch, Camarero, J Julio, Cavin, Liam, Claessens, Hugues, Drobyshev, Igor, Garamszegi, Balázs, Grabner, Michael, Hacket-Pain, Andrew, Hartl, Claudia, Hevia, Andrea, Janda, Pavel, Jump, Alistair S, Kazimirovic, Marko, Keren, Srdjan, Kreyling, Juergen, Land, Alexander, Latte, Nicolas, Levanič, Tom, van der Maaten, Ernst, van der Maaten-Theunissen, Marieke, Martínez-Sancho, Elisabet, Menzel, Annette, Mikoláš, Martin, Motta, Renzo, Muffler, Lena, Nola, Paola, Panayotov, Momchil, Petritan, Any Mary, Petritan, Ion Catalin, Popa, Ionel, Prislan, Peter, Roibu, Catalin-Constantin, Rydval, Miloš, Sánchez-Salguero, Raul, Scharnweber, Tobias, Stajić, Branko, Svoboda, Miroslav, Tegel, Willy, Teodosiu, Marius, Toromani, Elvin, Trotsiuk, Volodymyr, Turcu, Daniel-Ond, Weigel, Robert, Wilmking, Martin, Zang, Christian, Zlatanov, Tzvetan, Trouet, Valerie, Dorado-Linan, I., Ayarzaguena, B., Babst, F., Xu, G., Gil, L., Battipaglia, G., Buras, A., Cada, V., Camarero, J. J., Cavin, L., Claessens, H., Drobyshev, I., Garamszegi, B., Grabner, M., Hacket-Pain, A., Hartl, C., Hevia, A., Janda, P., Jump, A. S., Kazimirovic, M., Keren, S., Kreyling, J., Land, A., Latte, N., Levanic, T., van der Maaten, E., van der Maaten-Theunissen, M., Martinez-Sancho, E., Menzel, A., Mikolas, M., Motta, R., Muffler, L., Nola, P., Panayotov, M., Petritan, A. M., Petritan, I. C., Popa, I., Prislan, P., Roibu, C. -C., Rydval, M., Sanchez-Salguero, R., Scharnweber, T., Stajic, B., Svoboda, M., Tegel, W., Teodosiu, M., Toromani, E., Trotsiuk, V., Turcu, D. -O., Weigel, R., Wilmking, M., Zang, C., Zlatanov, T., and Trouet, V.

Subjects

Air Movements, Climate Research, Multidisciplinary, atmosferska dinamika, Forest Science, Climate Change, climate-change impacts, Air Movement, General Physics and Astronomy, General Chemistry, Geofísica, Forests, okoljski vpliv, environmental impact, General Biochemistry, Genetics and Molecular Biology, Carbon, ekologija podnebnih sprememb, vpliv podnebnih sprememb, Meteorology and Atmospheric Sciences, Fagus, Forest, atmospheric dynamics, udc:630*111, climate-change ecology

Abstract

The mechanistic pathways connecting ocean-atmosphere variability and terrestrial productivity are well-established theoretically, but remain challenging to quantify empirically. Such quantification will greatly improve the assessment and prediction of changes in terrestrial carbon sequestration in response to dynamically induced climatic extremes. The jet stream latitude (JSL) over the North Atlantic-European domain provides a synthetic and robust physical framework that integrates climate variability not accounted for by atmospheric circulation patterns alone. Surface climate impacts of north-south summer JSL displacements are not uniform across Europe, but rather create a northwestern-southeastern dipole in forest productivity and radial-growth anomalies. Summer JSL variability over the eastern North Atlantic-European domain (5-40E) exerts the strongest impact on European beech, inducing anomalies of up to 30% in modelled gross primary productivity and 50% in radial tree growth. The net effects of JSL movements on terrestrial carbon fluxes depend on forest density, carbon stocks, and productivity imbalances across biogeographic regions. Here the authors show that extremes in the summer jet stream position over Europe create a beech forest productivity dipole between northwestern and southeastern Europe and can result in regional anomalies in forest carbon uptake and growth., This work was supported by Fundacio La Caixa through the Junior Leader Program (LCF/BQ/LR18/11640004) and the Universidad Politécnica de Madrid through the Programa Propio (PINV-18-SBSYN2-105-F1TXYR). The following authors acknowledge funding support. I.D.L.: Agnese N. Haury Visiting Scholar & Trainee Fellowship (Laboratory of Tree-Ring Research, University of Arizona), the Mobility Award Jose Castillejo, Ministry of Education, Spanish Government (CAS19/00331) and the Programa de Ayudas Beatriz Galindo, Secretaría de Estado de Universidades, Investigación, Desarrollo e Innovación (#BG20/00065). V.T.: National Science Foundation CAREER grant (AGS-1349942). B.A.: Spanish Ministry of Science and Innovation through the JeDiS project (RTI-2018-096402-B-I00). F.B.: project "Inside out" (#POIR.04.04.00-00-5F85/18-00) funded by the HOMING program of the Foundation for Polish Science co-financed by the European Union under the European Regional Development Fund. AB, AM, CSZ: Bavarian Ministry of Science and the Arts in the context of the Bavarian Climate Research Network (BayKliF). A.H.: PinCaR project (UHU-1266324) by ERD Funds, Andalucía Regional Government, Consejería de Economía, Conocimiento, Empresas y Universidad 2014-2020. EM-S: Swiss National Science Foundation project TRoxy (No. 200021_175888). A.S.J.: Natural Environment Research Council grants NE/V00929X/1 and NE/S010041/1. J.K., L.M., M.M.T., R.W., M.W.: research training group RESPONSE funded by the German Research Council (DFG Fi 846/8-1, DFG GRK2010). AMP: Romanian Ministry of Research, Innovation, and Digitization, Project-PN-19070506/Ctr. no. 12N/2019. I.C.P.: grant of the Romanian Ministry of Education and Research, CNCS-UEFISCDI within PNCDI III (PN-III-P4-ID-PCE-2020-2696). R.S.S.: DendrOlavide I (EQC2018-005303-P), Ministry of Science, Innovation and Universities, Spain; DendrOlavide II (IE19_074 UPO), VURECLIM (P20_00813) and VULBOS (UPO-1263216). T.L.: Slovenian Research Agency-research core funding no. P4-0107 Program research group "Forest Biology, Ecology and Technology". We thank Virgilio Gómez-Rubio for assistance and advice on the LMM development. We thank Christoph Dittmar, Wolfram Elling, and numerous students of the University of Applied Sciences Weihenstephan-Triesdorf for providing European beech tree-ring chronologies.

Published

2022