Fir (Abies spp.) stand biomass additive model for Eurasia sensitive to winter temperature and annual precipitation-Reference-Cited by-同舟云学术

Fir (Abies spp.) stand biomass additive model for Eurasia sensitive to winter temperature and annual precipitation

Published:2019-09-01 Issue:3-4 Volume:65 Page:166-179
ISSN:0323-1046
Container-title:Central European Forestry Journal
language:en
Short-container-title:

Author:

Usoltsev Vladimir A.¹²,Merganičová Katarína³⁴,Konôpka Bohdan⁴⁵,Osmirko Anna A.¹,Tsepordey Ivan S.²,Chasovskikh Viktor P.¹

Affiliation:

1. Ural State Forest Engineering University , Sibirskii trakt str., 37, Yekaterinburg , 620100 Russian Federation

2. Botanical Garden, Russian Academy of Sciences , Ural Branch, 8 Marta str., 202a, Yekaterinburg , 620144 Russian Federation

3. Technical University in Zvolen , Faculty of Forestry , T. G. Masaryka 24, SK – 960 01 Zvolen , Slovak Republic

4. Czech University of Life Sciences Prague , Faculty of Forestry and Wood Sciences , Kamýcká 129, CZ – 165 21 Praha 6 – Suchdol, Czech Republic

5. National Forest Centre - Forest Research Institute Zvolen , T. G. Masaryka 2175/22, SK – 960 01 Zvolen , Slovak Republic

Abstract

Abstract Climate change, especially modified courses of temperature and precipitation, has a significant impact on forest functioning and productivity. Moreover, some alterations in tree biomass allocation (e.g. root to shoot ratio, foliage to wood parts) might be expected in these changing ecological conditions. Therefore, we attempted to model fir stand biomass (t ha−1) along the trans-Eurasian hydrothermal gradients using the data from 272 forest stands. The model outputs suggested that all biomass components, except for the crown mass, change in a common pattern, but in different ratios. Specifically, in the range of mean January temperature and precipitation of −30°C to +10°C and 300 to 900 mm, fir stand biomass increases with both increasing temperature and precipitation. Under an assumed increase of January temperature by 1°C, biomass of roots and of all components of the aboveground biomass of fir stands increased (under the assumption that the precipitation level did not change). Similarly, an assumed increase in precipitation by 100 mm resulted in the increased biomass of roots and of all aboveground components. We conclude that fir seems to be a perspective taxon from the point of its productive properties in the ongoing process of climate change.

Publisher

Walter de Gruyter GmbH

Subject

Forestry

Link

https://www.sciendo.com/pdf/10.2478/forj-2019-0017

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