Forest type and height are important in shaping the altitudinal change of radial growth response to climate change

Liang, Penghong; Wang, Xiangping; Sun, Han; Fan, Yanwen; Wu, Yulian; Lin, Xiao; Chang, Jinfeng

doi:10.1038/s41598-018-37823-w

Cited by 19 publications

(11 citation statements)

References 51 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Strongest growth response of P. abies during the last century might be related to different disturbance history of stands, which may have affected the response to warming through the changing canopy structure [40]. Alternatively, species-related growth responses to climate were reported by several authors [39,51,52].…”

Section: Discussionmentioning

confidence: 99%

Growth Trends of Coniferous Species along Elevational Transects in the Central European Alps Indicate Decreasing Sensitivity to Climate Warming

Oberhuber

Bendler

Gamper

et al. 2020

Forests

View full text Add to dashboard Cite

Tree growth at high elevation in the Central European Alps (CEA) is strongly limited by low temperature during the growing season. We developed a tree ring series of co-occurring conifers (Swiss stone pine, Norway spruce, European larch) along elevational transects stretching from the subalpine zone to the krummholz limit (1630–2290 m asl; n = 503 trees) and evaluated whether trends in basal area increment (BAI) are in line with two phases of climate warming, which occurred from 1915–1953 and from 1975–2015. Unexpectedly, results revealed that at subalpine sites (i) intensified climate warming in recent decades did not lead to a corresponding increase in BAI and (ii) increase in summer temperature since 1915 primarily favored growth of larch and spruce, although Swiss stone pine dominates at high elevations in the Eastern CEA, and therefore was expected to mainly benefit from climate warming. At treeline, BAI increases in all species were above the level expected based on determined age trend, whereas at the krummholz limit only deciduous larch showed a minor growth increase. We explain missing adequate growth response to recent climate warming by strengthened competition for resources (nutrients, light, water) in increasingly denser stands at subalpine sites, and by frost desiccation injuries of evergreen tree species at the krummholz limit. To conclude, accurate forecasts of tree growth response to climate warming at high elevation must consider changes in stand density as well as species-specific sensitivity to climate variables beyond the growing season.

show abstract

Section: Discussionmentioning

confidence: 99%

Growth Trends of Coniferous Species along Elevational Transects in the Central European Alps Indicate Decreasing Sensitivity to Climate Warming

Oberhuber

Bendler

Gamper

et al. 2020

Forests

View full text Add to dashboard Cite

show abstract

“…Research in forestry, botany, and ecoclimates focuses on understanding the complex interplay of vegetation and climate. A number of methods investigate the impact of climate and weather on vegetation to explain the dynamics and functioning of plants, for example when exposed to climate warming [Liang et al 2019;Zellweger et al 2020]. Furthermore, climate can have a profound influence on the self-organization of plant ecosystems, which results in the formation of spatial patterns, such as labyrinths and gaps [Bastiaansen et al 2020;Pringle and Tarnita 2017].…”

Section: Related Workmentioning

confidence: 99%

“…The primary goals of ecoclimate research are to understand the growth response and functioning of vegetation according to changing climatic conditions [Liang et al 2019], the impact of vegetation on thermodynamics and the water cycle [Allan et al 2020], and the feedback loop of vegetation and the climate [Kovenock and Swann 2018]. Many of the current approaches for modeling ecoclimate processes rely on meteorological or macroclimate data, such as free-air temperature or open-field precipitation, that is measured in weather stations.…”

Section: Introductionmentioning

confidence: 99%

Ecoclimates

Pałubicki¹,

Makowski²,

Gajda³

et al. 2022

ACM Trans. Graph.

View full text Add to dashboard Cite

One of the greatest challenges to mankind is understanding the underlying principles of climate change. Over the last years, the role of forests in climate change has received increased attention. This is due to the observation that not only the atmosphere has a principal impact on vegetation growth but also that vegetation is contributing to local variations of weather resulting in diverse microclimates. The interconnection of plant ecosystems and weather is described and studied as ecoclimates. In this work we take steps towards simulating ecoclimates by modeling the feedback loops between vegetation, soil, and atmosphere. In contrast to existing methods that only describe the climate at a global scale, our model aims at simulating local variations of climate. Specifically, we model tree growth interactively in response to gradients of water, temperature and light. As a result, we are able to capture a range of ecoclimate phenomena that have not been modeled before, including geomorphic controls, forest edge effects, the Foehn effect and spatial vegetation patterning. To validate the plausibility of our method we conduct a comparative analysis to studies from ecology and climatology. Consequently, our method advances the state-of-the-art of generating highly realistic outdoor landscapes of vegetation.

show abstract

“…Heat spells combined with extended drought periods are, however, increasing worldwide and have negatively affected productivity [7], increased mortality [8,9] and induced shifts in species' distribution ranges and species composition [10][11][12]. Temperature increase may also positively affect forest productivity, for example, due to the positive effect on photosynthesis in mountains or high latitudes, which are energy limited and not water limited [13], and also due to the lengthening of the growing season [14,15]. Besides, the continuous increase in atmospheric carbon dioxide (eCO 2 ) acts as a fertilizer for plant growth-termed the "CO 2 fertilization effect" [16] because current CO 2 levels are far from being limiting for the photosynthetic carboxylation reactions in the chloroplasts of C3 plants [17].…”

Section: Introductionmentioning

confidence: 99%

Gains or Losses in Forest Productivity under Climate Change? The Uncertainty of CO2 Fertilization and Climate Effects

Sperlich

Nadal‐Sala

Gracia

et al. 2020

Climate

View full text Add to dashboard Cite

Global warming poses great challenges for forest managers regarding adaptation strategies and species choices. More frequent drought events and heat spells are expected to reduce growth and increase mortality. Extended growing seasons, warming and elevated CO2 (eCO2) can also positively affect forest productivity. We studied the growth, productivity and mortality of beech (Fagus sylvatica L.) and fir (Abies alba Mill.) in the Black Forest (Germany) under three climate change scenarios (representative concentration pathways (RCP): RCP2.6, RCP4.5, RCP8.5) using the detailed biogeochemical forest growth model GOTILWA+. Averaged over the entire simulation period, both species showed productivity losses in RCP2.6 (16–20%) and in RCP4.5 (6%), but productivity gains in RCP8.5 (11–17%). However, all three scenarios had a tipping point (between 2035–2060) when initial gains in net primary productivity (NPP) (6–29%) eventually turned into losses (1–26%). With eCO2 switched off, the losses in NPP were 26–51% in RCP2.6, 36–45% in RCP4.5 and 33–71% in RCP8.5. Improved water-use efficiency dampened drought effects on NPP between 4 and 5%. Tree mortality increased, but without notably affecting forest productivity. Concluding, cultivation of beech and fir may still be possible in the study region, although severe productivity losses can be expected in the coming decades, which will strongly depend on the dampening CO2 fertilization effect.

show abstract

Forest type and height are important in shaping the altitudinal change of radial growth response to climate change

Cited by 19 publications

References 51 publications

Growth Trends of Coniferous Species along Elevational Transects in the Central European Alps Indicate Decreasing Sensitivity to Climate Warming

Growth Trends of Coniferous Species along Elevational Transects in the Central European Alps Indicate Decreasing Sensitivity to Climate Warming

Ecoclimates

Gains or Losses in Forest Productivity under Climate Change? The Uncertainty of CO2 Fertilization and Climate Effects

Contact Info

Product

Resources

About