Ninety-five years of observed disturbance-based tree mortality modeled with climate-sensitive accelerated failure time models

Maringer, Janet; Stelzer, Anne-Sophie; Paul, Carola; Albrecht, Axel

doi:10.1007/s10342-020-01328-x

Cited by 20 publications

(17 citation statements)

References 80 publications

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“…Precipitation increases were also associated with increased loss in some regions. This has been found in other studies (Maringer et al, 2021; Neumann et al, 2017) and although appearing counterintuitive can arise due to increased competition after forest growth spurts (Condit et al, 2004; McDowell, 2018) and the decoupling between precipitation and soil moisture which, in areas of groundwater depletion like NW India, is common (Condon & Maxwell, 2019; Zaveri et al, 2016).…”

Section: Discussionmentioning

confidence: 51%

“…Impacts of climate change on forests are often largely dependent on geographical location and interactions between climate variables (Allen et al, 2010; Brito‐Morales et al, 2018; Maracchi et al, 2005) but have been shown to both positively and negatively affect forest growth, mortality, productivity and distribution, alongside impacting the capability to deal with other stressors like drought and fire (IPCC, 2019; Ovenden et al, 2021). Temperature increases are by far the most commonly studied climate driver of forest mortality (Chen et al, 2011; Heikkinen et al, 2020; Maringer et al, 2021; Seidl et al, 2017) and have been shown to directly impact forest distribution and growth (Garcia et al, 2014; Lenoir & Svenning, 2015). Changes in precipitation have also been shown to affect forest survival, most commonly precipitation decreases (Aiba & Kitayama, 2002; Bennett et al, 2015; Chen et al, 2017; Phillips et al, 2009; Taccoen et al, 2019; Zhang et al, 2017), but the relationships are often complex (Bateman et al, 2016; Seidl et al, 2017) and can be highly dependent on forest type, previous conditions and phenotypical adaptations of species (Das et al, 2013; Greenwood et al, 2017; McDowell, 2018).…”

Section: Introductionmentioning

confidence: 99%

“…Impacts of climate change on forests are often largely dependent on geographical location and interactions between climate variables (Allen et al, 2010;Brito-Morales et al, 2018;Maracchi et al, 2005) but have been shown to both positively and negatively affect forest growth, mortality, productivity and distribution, alongside impacting the capability to deal with other stressors like drought and fire (IPCC, 2019;Ovenden et al, 2021). Temperature increases are by far the most commonly studied climate driver of forest mortality (Chen et al, 2011;Heikkinen et al, 2020;Maringer et al, 2021;Seidl et al, 2017) and have been shown to directly impact forest distribution and growth (Garcia et al, 2014;Lenoir & Svenning, 2015).…”

Section: Introductionmentioning

confidence: 99%

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The role of climate in past forest loss in an ecologically important region of South Asia

Haughan

Pettorelli

Potts

et al. 2022

Global Change Biology

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Tropical forests in India have declined at an alarming rate over the past century, with extensive literature focusing on the high contributions of agricultural expansions to deforestation, while the effects of climate change have largely been overlooked. Climate change effects, such as increasing temperatures, drought and flooding, have already occurred, and are projected to worsen. Climate velocity, a metric that accounts for spatial heterogeneity in climate, can help identify contiguous areas under greater climate stress and potential climate refuges in addition to traditional temporal trends. Here, we examined the relative contribution of climate changes to forest loss in India during the period 2001–2018, at two spatial (regional and national) and two temporal (seasonal and annual) scales. This includes, for the first time, a characterization of climate velocity in the country. Our findings show that annual forest loss increased substantially over the 17‐year period examined (2001–2018), with the majority of forest loss occurring in the Northeast region. Decreases in temporal trends of temperature and precipitation were most associated with forest losses, but there was large spatial and seasonal variation in the relationship. In every region except the Northeast, forest losses were correlated with faster velocities of at least one climate variable but overlapping areas of high velocities were rare. Our findings indicate that climate changes have played an important role in India's past forest loss, but likely remain secondary to other factors at present. We stress concern for climates velocities recorded in the country, reaching 97 km year−1, and highlight that understanding the different regional and seasonal relationships between climatic conditions and forest distributions will be key to effective protection of the country's remaining forests as climate change accelerates.

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Section: Discussionmentioning

confidence: 51%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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The role of climate in past forest loss in an ecologically important region of South Asia

Haughan

Pettorelli

Potts

et al. 2022

Global Change Biology

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“…In addition, trees are more threatened when temperature is high or water availability is low (Brandl et al 2020). An effect of the soil nutritional properties has also been demonstrated (Maringer et al 2021). Finally, air pollution due to nitrogen, sulphur deposition and ozone can also contribute to the weakening of forest ecosystems (Dietze and Moorcroft 2011).…”

Section: Introductionmentioning

confidence: 97%

“…It has been presented as the combination of interchangeable predisposing, inciting, and contributing factors (Sinclair (1965). Predisposing factors reduce tree ability to resist to a stress on the long term, inciting factors are usually caused by extreme events (Maringer et al 2021) and contributing factors are often insects or pathogens that cause the nal decline through hydraulic failure or carbon starvation (McDowell et al 2008). This model based on different causes that interact at different time and spatial scales was popularized by the decline spiral in the 1980's (Manion 1981).…”

Section: Introductionmentioning

confidence: 99%

Spatial risk assessment of silver fir and Norway spruce dieback driven by climate warming

Piedallu

Dallery

Bresson

et al. 2022

Preprint

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Context: A significant forest decline has been noticed these last years in Europe. Managers need tools to better anticipate these massive events.Objectives: We evaluated the efficiency of easily available data about environmental conditions and stand characteristics to determine stand vulnerability and map different levels of risk.Methods: We combined remote sensing images, photo-interpretation, and digital models describing environmental conditions within a modelling approach to achieve spatial risk assessment of stand vulnerability. We focused on silver fir and Norway spruce stands in the Vosges mountains (8.800 km², north-east of France), where severe symptoms of decline are visible.Results: Easily available factors describing environmental conditions were used to design relevant vulnerability maps: using an independent dataset, we predicted two-times (Norway spruce) and ten-times (silver fir) higher mortality rates in the units with a high level of risk compared to the others. Norway spruce were predicted highly vulnerable on 33% of their area versus 7% for silver fir. Mortality was higher where the soils displayed low water availability and had suffered severe drying events these last years; it was lower when the species belonged to uneven-aged stands, in mixture, and in the absence of forest edges. Furthermore, the stands acclimatised to drought conditions were more resilient. Conclusions: Vulnerability maps based on easily available geographic information describing climate, soil, and topography can efficiently discriminate canopy mortality patterns over broad areas, and can be useful tools for managers to mitigate the effects of climate change on forests.

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Tree Mortality: Revisited Under Changed Climatic and Silvicultural Conditions

Pretzsch

Grote

2023

Progress in Botany

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Ninety-five years of observed disturbance-based tree mortality modeled with climate-sensitive accelerated failure time models

Cited by 20 publications

References 80 publications

The role of climate in past forest loss in an ecologically important region of South Asia

The role of climate in past forest loss in an ecologically important region of South Asia

Spatial risk assessment of silver fir and Norway spruce dieback driven by climate warming

Tree Mortality: Revisited Under Changed Climatic and Silvicultural Conditions

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