Light competition affects how tree growth and survival respond to climate

Competition between individuals is a key process that drives tree growth and survival in forests. Ecological theories predict that the effect of competition should be weaker in stressful environments. However, quantitative studies have failed to reach a consensus on the direction of the interaction...

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Published inThe Journal of ecology Vol. 113; no. 3; pp. 672 - 688
Main Authors Beauchamp, Nathéo, Kunstler, Georges, Touzot, Laura, Ruiz‐Benito, Paloma, Cienciala, Emil, Dahlgren, Jonas, Hawryło, Paweł, Klopčič, Matija, Lehtonen, Aleksi, Šebeň, Vladimír, Socha, Jarosław, Zavala, Miguel A., Courbaud, Benoit
Format Journal Article
LanguageEnglish
Published Oxford Blackwell Publishing Ltd 01.03.2025
Wiley
Subjects
Allometry
Aridity
climate
Climate change
climatic gradients
cold
cold stress
Competition
continental range
dry environmental conditions
Ecology
Ecology, environment
Ekologi
Environmental impact
forest stands
Forests
Gradients
individual‐based model
Life Sciences
Light
light competition
Niches
Plant species
plant–climate interactions
plant–plant interactions
Quantitative research
Ray tracing
Scandinavia
Shade
shade tolerance
Spain
Species
Survival
temperature
tree crown
tree growth
tree growth and survival
Trees
Scandinavia
Spain
climatic gradients
tree growth and survival
plant–plant interactions
shade tolerance
continental range
light competition
plant–climateinteractions
individual-based model
Online AccessGet full text
ISSN0022-0477
1365-2745
1365-2745
DOI10.1111/1365-2745.14489

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Abstract Competition between individuals is a key process that drives tree growth and survival in forests. Ecological theories predict that the effect of competition should be weaker in stressful environments. However, quantitative studies have failed to reach a consensus on the direction of the interaction between climate and competition. In this study, we demonstrate that this interaction appears clearly when we explicitly focus on light competition. We analysed the effect of light competition on tree growth and survival along both temperature and aridity gradients for the 33 major European tree species. We collected forest inventories from nine European countries, encompassing over 1 million trees from Spain to Scandinavia. We used species‐specific crown allometric equations to connect this extensive database to the SamsaraLight ray tracing model and to calculate a tree‐based light competition index from the light intercepted by the tree crown. Within a given species' climatic niche, the effect of light competition on tree growth and survival decreased towards both the dry and cold margins, supporting the stress gradient hypothesis. Climate mainly affected tree growth in light, with slower growth in drier or colder conditions. In contrast, for survival, climate mainly affected trees in shade, with better survival in the dry or cold stress margins. Among species, the mean sensitivity of tree growth and survival to light competition decreased with increasing mean aridity niche and shade tolerance of the species. Synthesis. Our study emphasises the importance of considering species‐specific interactions between light competition and climate on tree growth and survival. The impact of climate change on an individual tree is likely to depend on its light competition status within the forest stand, as well as its species‐specific climatic niche and shade tolerance. Résumé La compétition entre individus est un processus clé qui détermine la croissance et la survie des arbres des forêts. Les théories écologiques prévoient que l'effet de la compétition devrait être plus faible dans les environnements stressants. Cependant, les études quantitatives ne sont pas parvenues à un consensus sur la direction de l'interaction entre climat et compétition. Dans cette étude, nous démontrons que cette interaction apparaît clairement lorsque nous nous concentrons explicitement sur la compétition pour la lumière. Nous avons analysé l'effet de la compétition pour la lumière sur la croissance et la survie des arbres le long des gradients de température et d'aridité pour les 33 principales espèces d'arbres européennes. Nous avons rassemblé des inventaires forestiers de neuf pays européens, couvrant plus d'un million d'arbres de l'Espagne à la Scandinavie. Nous avons utilisé des équations allométriques de houppiers spécifiques à chaque espèce pour relier cette vaste base de données au modèle de traçage de rayons lumineux SamsaraLight. Cela nous a permis de calculer un indice de compétition pour la lumière, basé sur la lumière interceptée par le houppier de l'arbre. Au sein de la niche climatique d'une espèce, l'effet de la compétition pour la lumière sur la croissance et la survie des arbres diminue vers la marge aride et la marge froide, soutenant l'hypothèse du gradient de stress. Le climat affecte principalement la croissance des arbres en pleine lumière, avec une croissance plus lente dans des conditions plus arides ou plus froides. En revanche, pour la survie, le climat affecte principalement les arbres à l'ombre, avec une meilleure survie dans les marges stressantes aride ou froide. Lorsque l'on compare les espèces entre elles, la sensibilité moyenne de la croissance et de la survie des arbres à la compétition pour la lumière diminue avec l'augmentation de l'aridité de la niche climatique moyenne et de la tolérance à l'ombre des espèces. Synthèse. Notre étude souligne l'importance de prendre en compte l'interaction entre compétition pour la lumière et climat pour mieux prédire la croissance et la survie des arbres. L'impact du changement climatique sur un arbre dépendra probablement de son statut de compétition pour la lumière au sein du peuplement forestier, ainsi que de la niche climatique et de la tolérance à l'ombre de l'espèce. We analysed the effect of light competition on tree growth and survival along both temperature and aridity gradients for the 33 major European tree species. We used forest data from nine European countries and the SamsaraLight ray tracing model. We found that the effect of light competition is weaker in stressful environments.
AbstractList Competition between individuals is a key process that drives tree growth and survival in forests. Ecological theories predict that the effect of competition should be weaker in stressful environments. However, quantitative studies have failed to reach a consensus on the direction of the interaction between climate and competition. In this study, we demonstrate that this interaction appears clearly when we explicitly focus on light competition.We analysed the effect of light competition on tree growth and survival along both temperature and aridity gradients for the 33 major European tree species. We collected forest inventories from nine European countries, encompassing over 1 million trees from Spain to Scandinavia. We used species‐specific crown allometric equations to connect this extensive database to the SamsaraLight ray tracing model and to calculate a tree‐based light competition index from the light intercepted by the tree crown.Within a given species' climatic niche, the effect of light competition on tree growth and survival decreased towards both the dry and cold margins, supporting the stress gradient hypothesis. Climate mainly affected tree growth in light, with slower growth in drier or colder conditions. In contrast, for survival, climate mainly affected trees in shade, with better survival in the dry or cold stress margins.Among species, the mean sensitivity of tree growth and survival to light competition decreased with increasing mean aridity niche and shade tolerance of the species.Synthesis. Our study emphasises the importance of considering species‐specific interactions between light competition and climate on tree growth and survival. The impact of climate change on an individual tree is likely to depend on its light competition status within the forest stand, as well as its species‐specific climatic niche and shade tolerance.
Competition between individuals is a key process that drives tree growth and survival in forests. Ecological theories predict that the effect of competition should be weaker in stressful environments. However, quantitative studies have failed to reach a consensus on the direction of the interaction between climate and competition. In this study, we demonstrate that this interaction appears clearly when we explicitly focus on light competition. We analysed the effect of light competition on tree growth and survival along both temperature and aridity gradients for the 33 major European tree species. We collected forest inventories from nine European countries, encompassing over 1 million trees from Spain to Scandinavia. We used species-specific crown allometric equations to connect this extensive database to the SamsaraLight ray tracing model and to calculate a tree-based light competition index from the light intercepted by the tree crown. Within a given species' climatic niche, the effect of light competition on tree growth and survival decreased towards both the dry and cold margins, supporting the stress gradient hypothesis. Climate mainly affected tree growth in light, with slower growth in drier or colder conditions. In contrast, for survival, climate mainly affected trees in shade, with better survival in the dry or cold stress margins. Among species, the mean sensitivity of tree growth and survival to light competition decreased with increasing mean aridity niche and shade tolerance of the species. Synthesis. Our study emphasises the importance of considering species-specific interactions between light competition and climate on tree growth and survival. The impact of climate change on an individual tree is likely to depend on its light competition status within the forest stand, as well as its species-specific climatic niche and shade tolerance.La comp & eacute;tition entre individus est un processus cl & eacute; qui d & eacute;termine la croissance et la survie des arbres des for & ecirc;ts. Les th & eacute;ories & eacute;cologiques pr & eacute;voient que l'effet de la comp & eacute;tition devrait & ecirc;tre plus faible dans les environnements stressants. Cependant, les & eacute;tudes quantitatives ne sont pas parvenues & agrave; un consensus sur la direction de l'interaction entre climat et comp & eacute;tition. Dans cette & eacute;tude, nous d & eacute;montrons que cette interaction appara & icirc;t clairement lorsque nous nous concentrons explicitement sur la comp & eacute;tition pour la lumi & egrave;re. Nous avons analys & eacute; l'effet de la comp & eacute;tition pour la lumi & egrave;re sur la croissance et la survie des arbres le long des gradients de temp & eacute;rature et d'aridit & eacute; pour les 33 principales esp & egrave;ces d'arbres europ & eacute;ennes. Nous avons rassembl & eacute; des inventaires forestiers de neuf pays europ & eacute;ens, couvrant plus d'un million d'arbres de l'Espagne & agrave; la Scandinavie. Nous avons utilis & eacute; des & eacute;quations allom & eacute;triques de houppiers sp & eacute;cifiques & agrave; chaque esp & egrave;ce pour relier cette vaste base de donn & eacute;es au mod & egrave;le de tra & ccedil;age de rayons lumineux SamsaraLight. Cela nous a permis de calculer un indice de comp & eacute;tition pour la lumi & egrave;re, bas & eacute; sur la lumi & egrave;re intercept & eacute;e par le houppier de l'arbre. Au sein de la niche climatique d'une esp & egrave;ce, l'effet de la comp & eacute;tition pour la lumi & egrave;re sur la croissance et la survie des arbres diminue vers la marge aride et la marge froide, soutenant l'hypoth & egrave;se du gradient de stress. Le climat affecte principalement la croissance des arbres en pleine lumi & egrave;re, avec une croissance plus lente dans des conditions plus arides ou plus froides. En revanche, pour la survie, le climat affecte principalement les arbres & agrave; l'ombre, avec une meilleure survie dans les marges stressantes aride ou froide. Lorsque l'on compare les esp & egrave;ces entre elles, la sensibilit & eacute; moyenne de la croissance et de la survie des arbres & agrave; la comp & eacute;tition pour la lumi & egrave;re diminue avec l'augmentation de l'aridit & eacute; de la niche climatique moyenne et de la tol & eacute;rance & agrave; l'ombre des esp & egrave;ces. Synth & egrave;se. Notre & eacute;tude souligne l'importance de prendre en compte l'interaction entre comp & eacute;tition pour la lumi & egrave;re et climat pour mieux pr & eacute;dire la croissance et la survie des arbres. L'impact du changement climatique sur un arbre d & eacute;pendra probablement de son statut de comp & eacute;tition pour la lumi & egrave;re au sein du peuplement forestier, ainsi que de la niche climatique et de la tol & eacute;rance & agrave; l'ombre de l'esp & egrave;ce.
1- Competition between individuals is a key process that drives tree growth and survival in forests. Ecological theories predict that the effect of competition should be weaker in stressful environments. However, quantitative studies have failed to reach a consensus on the direction of the interaction between climate and competition. In this study, we demonstrate that this interaction appears clearly when we explicitly focus on light competition. 2- We analysed the effect of light competition on tree growth and survival along both temperature and aridity gradients for the 33 major European tree species. We collected forest inventories from nine European countries, encompassing over 1 million trees from Spain to Scandinavia. We used species‐specific crown allometric equations to connect this extensive database to the SamsaraLight ray tracing model and to calculate a tree‐based light competition index from the light intercepted by the tree crown.3- Within a given species' climatic niche, the effect of light competition on tree growth and survival decreased towards both the dry and cold margins, supporting the stress gradient hypothesis. Climate mainly affected tree growth in light, with slower growth in drier or colder conditions. In contrast, for survival, climate mainly affected trees in shade, with better survival in the dry or cold stress margins.4- Among species, the mean sensitivity of tree growth and survival to light competition decreased with increasing mean aridity niche and shade tolerance of the species. 5- Synthesis. Our study emphasises the importance of considering species‐specific interactions between light competition and climate on tree growth and survival. The impact of climate change on an individual tree is likely to depend on its light competition status within the forest stand, as well as its species‐specific climatic niche and shade tolerance. 1- La compétition entre individus est un processus clé qui détermine la croissance et la survie des arbres des forêts. Les théories écologiques prévoient que l'effet de la compétition devrait être plus faible dans les environnements stressants. Cependant, les études quantitatives ne sont pas parvenues à un consensus sur la direction de l'interaction entre climat et compétition. Dans cette étude, nous démontrons que cette interaction apparaît clairement lorsque nous nous concentrons explicitement sur la compétition pour la lumière. 2- Nous avons analysé l'effet de la compétition pour la lumière sur la croissance et la survie des arbres le long des gradients de température et d'aridité pour les 33 principales espèces d'arbres européennes. Nous avons rassemblé des inventaires forestiers de neuf pays européens, couvrant plus d'un million d'arbres de l'Espagne à la Scandinavie. Nous avons utilisé des équations allométriques de houppiers spécifiques à chaque espèce pour relier cette vaste base de données au modèle de traçage de rayons lumineux SamsaraLight. Cela nous a permis de calculer un indice de compétition pour la lumière, basé sur la lumière interceptée par le houppier de l'arbre. 3- Au sein de la niche climatique d'une espèce, l'effet de la compétition pour la lumière sur la croissance et la survie des arbres diminue vers la marge aride et la marge froide, soutenant l'hypothèse du gradient de stress. Le climat affecte principalement la croissance des arbres en pleine lumière, avec une croissance plus lente dans des conditions plus arides ou plus froides. En revanche, pour la survie, le climat affecte principalement les arbres à l'ombre, avec une meilleure survie dans les marges stressantes aride ou froide. 4- Lorsque l'on compare les espèces entre elles, la sensibilité moyenne de la croissance et de la survie des arbres à la compétition pour la lumière diminue avec l'augmentation de l'aridité de la niche climatique moyenne et de la tolérance à l'ombre des espèces. 5- Synthèse. Notre étude souligne l'importance de prendre en compte l'interaction entre compétition pour la lumière et climat pour mieux prédire la croissance et la survie des arbres. L'impact du changement climatique sur un arbre dépendra probablement de son statut de compétition pour la lumière au sein du peuplement forestier, ainsi que de la niche climatique et de la tolérance à l'ombre de l'espèce.
Competition between individuals is a key process that drives tree growth and survival in forests. Ecological theories predict that the effect of competition should be weaker in stressful environments. However, quantitative studies have failed to reach a consensus on the direction of the interaction between climate and competition. In this study, we demonstrate that this interaction appears clearly when we explicitly focus on light competition. We analysed the effect of light competition on tree growth and survival along both temperature and aridity gradients for the 33 major European tree species. We collected forest inventories from nine European countries, encompassing over 1 million trees from Spain to Scandinavia. We used species‐specific crown allometric equations to connect this extensive database to the SamsaraLight ray tracing model and to calculate a tree‐based light competition index from the light intercepted by the tree crown. Within a given species' climatic niche, the effect of light competition on tree growth and survival decreased towards both the dry and cold margins, supporting the stress gradient hypothesis. Climate mainly affected tree growth in light, with slower growth in drier or colder conditions. In contrast, for survival, climate mainly affected trees in shade, with better survival in the dry or cold stress margins. Among species, the mean sensitivity of tree growth and survival to light competition decreased with increasing mean aridity niche and shade tolerance of the species. Synthesis. Our study emphasises the importance of considering species‐specific interactions between light competition and climate on tree growth and survival. The impact of climate change on an individual tree is likely to depend on its light competition status within the forest stand, as well as its species‐specific climatic niche and shade tolerance. Résumé La compétition entre individus est un processus clé qui détermine la croissance et la survie des arbres des forêts. Les théories écologiques prévoient que l'effet de la compétition devrait être plus faible dans les environnements stressants. Cependant, les études quantitatives ne sont pas parvenues à un consensus sur la direction de l'interaction entre climat et compétition. Dans cette étude, nous démontrons que cette interaction apparaît clairement lorsque nous nous concentrons explicitement sur la compétition pour la lumière. Nous avons analysé l'effet de la compétition pour la lumière sur la croissance et la survie des arbres le long des gradients de température et d'aridité pour les 33 principales espèces d'arbres européennes. Nous avons rassemblé des inventaires forestiers de neuf pays européens, couvrant plus d'un million d'arbres de l'Espagne à la Scandinavie. Nous avons utilisé des équations allométriques de houppiers spécifiques à chaque espèce pour relier cette vaste base de données au modèle de traçage de rayons lumineux SamsaraLight. Cela nous a permis de calculer un indice de compétition pour la lumière, basé sur la lumière interceptée par le houppier de l'arbre. Au sein de la niche climatique d'une espèce, l'effet de la compétition pour la lumière sur la croissance et la survie des arbres diminue vers la marge aride et la marge froide, soutenant l'hypothèse du gradient de stress. Le climat affecte principalement la croissance des arbres en pleine lumière, avec une croissance plus lente dans des conditions plus arides ou plus froides. En revanche, pour la survie, le climat affecte principalement les arbres à l'ombre, avec une meilleure survie dans les marges stressantes aride ou froide. Lorsque l'on compare les espèces entre elles, la sensibilité moyenne de la croissance et de la survie des arbres à la compétition pour la lumière diminue avec l'augmentation de l'aridité de la niche climatique moyenne et de la tolérance à l'ombre des espèces. Synthèse. Notre étude souligne l'importance de prendre en compte l'interaction entre compétition pour la lumière et climat pour mieux prédire la croissance et la survie des arbres. L'impact du changement climatique sur un arbre dépendra probablement de son statut de compétition pour la lumière au sein du peuplement forestier, ainsi que de la niche climatique et de la tolérance à l'ombre de l'espèce. We analysed the effect of light competition on tree growth and survival along both temperature and aridity gradients for the 33 major European tree species. We used forest data from nine European countries and the SamsaraLight ray tracing model. We found that the effect of light competition is weaker in stressful environments.
Competition between individuals is a key process that drives tree growth and survival in forests. Ecological theories predict that the effect of competition should be weaker in stressful environments. However, quantitative studies have failed to reach a consensus on the direction of the interaction between climate and competition. In this study, we demonstrate that this interaction appears clearly when we explicitly focus on light competition. We analysed the effect of light competition on tree growth and survival along both temperature and aridity gradients for the 33 major European tree species. We collected forest inventories from nine European countries, encompassing over 1 million trees from Spain to Scandinavia. We used species‐specific crown allometric equations to connect this extensive database to the SamsaraLight ray tracing model and to calculate a tree‐based light competition index from the light intercepted by the tree crown. Within a given species' climatic niche, the effect of light competition on tree growth and survival decreased towards both the dry and cold margins, supporting the stress gradient hypothesis. Climate mainly affected tree growth in light, with slower growth in drier or colder conditions. In contrast, for survival, climate mainly affected trees in shade, with better survival in the dry or cold stress margins. Among species, the mean sensitivity of tree growth and survival to light competition decreased with increasing mean aridity niche and shade tolerance of the species. Synthesis. Our study emphasises the importance of considering species‐specific interactions between light competition and climate on tree growth and survival. The impact of climate change on an individual tree is likely to depend on its light competition status within the forest stand, as well as its species‐specific climatic niche and shade tolerance. La compétition entre individus est un processus clé qui détermine la croissance et la survie des arbres des forêts. Les théories écologiques prévoient que l'effet de la compétition devrait être plus faible dans les environnements stressants. Cependant, les études quantitatives ne sont pas parvenues à un consensus sur la direction de l'interaction entre climat et compétition. Dans cette étude, nous démontrons que cette interaction apparaît clairement lorsque nous nous concentrons explicitement sur la compétition pour la lumière. Nous avons analysé l'effet de la compétition pour la lumière sur la croissance et la survie des arbres le long des gradients de température et d'aridité pour les 33 principales espèces d'arbres européennes. Nous avons rassemblé des inventaires forestiers de neuf pays européens, couvrant plus d'un million d'arbres de l'Espagne à la Scandinavie. Nous avons utilisé des équations allométriques de houppiers spécifiques à chaque espèce pour relier cette vaste base de données au modèle de traçage de rayons lumineux SamsaraLight. Cela nous a permis de calculer un indice de compétition pour la lumière, basé sur la lumière interceptée par le houppier de l'arbre. Au sein de la niche climatique d'une espèce, l'effet de la compétition pour la lumière sur la croissance et la survie des arbres diminue vers la marge aride et la marge froide, soutenant l'hypothèse du gradient de stress. Le climat affecte principalement la croissance des arbres en pleine lumière, avec une croissance plus lente dans des conditions plus arides ou plus froides. En revanche, pour la survie, le climat affecte principalement les arbres à l'ombre, avec une meilleure survie dans les marges stressantes aride ou froide. Lorsque l'on compare les espèces entre elles, la sensibilité moyenne de la croissance et de la survie des arbres à la compétition pour la lumière diminue avec l'augmentation de l'aridité de la niche climatique moyenne et de la tolérance à l'ombre des espèces. Synthèse. Notre étude souligne l'importance de prendre en compte l'interaction entre compétition pour la lumière et climat pour mieux prédire la croissance et la survie des arbres. L'impact du changement climatique sur un arbre dépendra probablement de son statut de compétition pour la lumière au sein du peuplement forestier, ainsi que de la niche climatique et de la tolérance à l'ombre de l'espèce.
Author Courbaud, Benoit
Lehtonen, Aleksi
Klopčič, Matija
Beauchamp, Nathéo
Socha, Jarosław
Kunstler, Georges
Šebeň, Vladimír
Zavala, Miguel A.
Dahlgren, Jonas
Ruiz‐Benito, Paloma
Hawryło, Paweł
Cienciala, Emil
Touzot, Laura
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  organization: Université Grenoble Alpes, LESSEM, INRAE
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  surname: Kunstler
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  fullname: Dahlgren, Jonas
  organization: Swedish University of Agricultural Sciences
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  fullname: Hawryło, Paweł
  organization: University of Agriculture in Krakow
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  fullname: Klopčič, Matija
  organization: University of Ljubljana
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  fullname: Lehtonen, Aleksi
  organization: Natural Resources Institute Finland (Luke)
– sequence: 10
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  surname: Šebeň
  fullname: Šebeň, Vladimír
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  surname: Socha
  fullname: Socha, Jarosław
  organization: University of Agriculture in Krakow
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  givenname: Miguel A.
  surname: Zavala
  fullname: Zavala, Miguel A.
  organization: Universidad de Alcala
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  givenname: Benoit
  orcidid: 0000-0002-3050-9559
  surname: Courbaud
  fullname: Courbaud, Benoit
  organization: Université Grenoble Alpes, LESSEM, INRAE
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https://res.slu.se/id/publ/141194$$DView record from Swedish Publication Index
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Issue 3
Keywords climatic gradients
tree growth and survival
plant–plant interactions
shade tolerance
continental range
light competition
plant–climateinteractions
individual-based model
Language English
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Snippet Competition between individuals is a key process that drives tree growth and survival in forests. Ecological theories predict that the effect of competition...
1- Competition between individuals is a key process that drives tree growth and survival in forests. Ecological theories predict that the effect of competition...
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SubjectTerms Allometry
Aridity
climate
Climate change
climatic gradients
cold
cold stress
Competition
continental range
dry environmental conditions
Ecology
Ecology, environment
Ekologi
Environmental impact
forest stands
Forests
Gradients
individual‐based model
Life Sciences
Light
light competition
Niches
Plant species
plant–climate interactions
plant–plant interactions
Quantitative research
Ray tracing
Scandinavia
Shade
shade tolerance
Spain
Species
Survival
temperature
tree crown
tree growth
tree growth and survival
Trees
Title Light competition affects how tree growth and survival respond to climate
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Volume 113
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