Growing‐season frost is a better predictor of tree growth than mean annual temperature in boreal mixedwood forest plantations

Increase in frost damage to trees due to earlier spring dehardening could outweigh the expected increase in forest productivity caused by climate warming. We quantified the impact of growing‐season frosts on the performance of three spruce species (white, black, and Norway spruce) and various seed s...

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Published inGlobal change biology Vol. 26; no. 11; pp. 6537 - 6554
Main Authors Marquis, Benjamin, Bergeron, Yves, Simard, Martin, Tremblay, Francine
Format Journal Article
LanguageEnglish
Published England Blackwell Publishing Ltd 01.11.2020
Subjects
Annual
apical meristems
boreal forest
Boreal forests
Canada
Climate
Climate change
Climate prediction
ecotones
Forest productivity
Forests
Frost
Frost damage
frost injury
frost resistance
frost rings
Global warming
Growing season
growing‐season frosts
Growth
growth retardation
Habitat selection
Height
Meristems
Norway
Picea
Picea abies
Picea glauca
Picea mariana
Pine trees
Plantations
provenance
Seasons
Species
stem analysis
summer
sustainable forest management
Temperate forests
Temperature
tree dormancy
tree growth
Tree rings
Trees
Canada
Norway
growing-season frosts
sustainable forest management
boreal forest
tree dormancy
forest productivity
frost rings
stem analysis
Picea
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Abstract Increase in frost damage to trees due to earlier spring dehardening could outweigh the expected increase in forest productivity caused by climate warming. We quantified the impact of growing‐season frosts on the performance of three spruce species (white, black, and Norway spruce) and various seed sources with different frost tolerance in two plantations, established on both sides of the eastern Canadian boreal‐temperate forest ecotone. The objectives of this study were to determine (a) if spruce species and seed sources planted in sites far from their natural provenance would be less adapted to local site conditions, leading to increased frost damage and reduced height growth; (b) at which height above the ground growing‐season frosts ceased to damage apical meristems; and (c) if height growth was best predicted by extreme climatic events (growing‐season frosts) or by mean annual or summer temperature. At each site and for all spruce species and seed sources, we cross‐sectioned spruce trees at different heights above the ground. Tree rings were cross‐dated and screened for frost rings, which were then given a severity score based on cellular damage. Frost severity reduced height growth of all spruce species and provenances at both sites. Height growth of the non‐native Norway spruce was the most reduced by frost severity and was the smallest species at both sites. Frost caused the highest growth reduction in white spruce at the boreal mixedwood site and had the least effect on black spruce at both sites. For all spruce species, height growth was affected up to 2 m above the ground. Model selection based on corrected Akaike's information criteria (AICc) identified that minimum temperature in May was by far the best climate variable predicting tree growth (AICc weight = 1), highlighting the importance of considering extreme climatic events, which are likely to increase in the future. Growing‐season frosts reduce spruce height growth and more importantly affects white spruce compared to black spruce in plantations at the boreal‐temperate forest ecotone of western Québec. Growing‐season frosts also better predict tree height increment compared to more conventional climate variables such as mean annual temperature and mean summer temperature.
AbstractList Increase in frost damage to trees due to earlier spring dehardening could outweigh the expected increase in forest productivity caused by climate warming. We quantified the impact of growing-season frosts on the performance of three spruce species (white, black, and Norway spruce) and various seed sources with different frost tolerance in two plantations, established on both sides of the eastern Canadian boreal-temperate forest ecotone. The objectives of this study were to determine (a) if spruce species and seed sources planted in sites far from their natural provenance would be less adapted to local site conditions, leading to increased frost damage and reduced height growth; (b) at which height above the ground growing-season frosts ceased to damage apical meristems; and (c) if height growth was best predicted by extreme climatic events (growing-season frosts) or by mean annual or summer temperature. At each site and for all spruce species and seed sources, we cross-sectioned spruce trees at different heights above the ground. Tree rings were cross-dated and screened for frost rings, which were then given a severity score based on cellular damage. Frost severity reduced height growth of all spruce species and provenances at both sites. Height growth of the non-native Norway spruce was the most reduced by frost severity and was the smallest species at both sites. Frost caused the highest growth reduction in white spruce at the boreal mixedwood site and had the least effect on black spruce at both sites. For all spruce species, height growth was affected up to 2 m above the ground. Model selection based on corrected Akaike's information criteria (AICc) identified that minimum temperature in May was by far the best climate variable predicting tree growth (AICc weight = 1), highlighting the importance of considering extreme climatic events, which are likely to increase in the future.
Increase in frost damage to trees due to earlier spring dehardening could outweigh the expected increase in forest productivity caused by climate warming. We quantified the impact of growing‐season frosts on the performance of three spruce species (white, black, and Norway spruce) and various seed sources with different frost tolerance in two plantations, established on both sides of the eastern Canadian boreal‐temperate forest ecotone. The objectives of this study were to determine (a) if spruce species and seed sources planted in sites far from their natural provenance would be less adapted to local site conditions, leading to increased frost damage and reduced height growth; (b) at which height above the ground growing‐season frosts ceased to damage apical meristems; and (c) if height growth was best predicted by extreme climatic events (growing‐season frosts) or by mean annual or summer temperature. At each site and for all spruce species and seed sources, we cross‐sectioned spruce trees at different heights above the ground. Tree rings were cross‐dated and screened for frost rings, which were then given a severity score based on cellular damage. Frost severity reduced height growth of all spruce species and provenances at both sites. Height growth of the non‐native Norway spruce was the most reduced by frost severity and was the smallest species at both sites. Frost caused the highest growth reduction in white spruce at the boreal mixedwood site and had the least effect on black spruce at both sites. For all spruce species, height growth was affected up to 2 m above the ground. Model selection based on corrected Akaike's information criteria (AICc) identified that minimum temperature in May was by far the best climate variable predicting tree growth (AICc weight = 1), highlighting the importance of considering extreme climatic events, which are likely to increase in the future.
Increase in frost damage to trees due to earlier spring dehardening could outweigh the expected increase in forest productivity caused by climate warming. We quantified the impact of growing-season frosts on the performance of three spruce species (white, black, and Norway spruce) and various seed sources with different frost tolerance in two plantations, established on both sides of the eastern Canadian boreal-temperate forest ecotone. The objectives of this study were to determine (a) if spruce species and seed sources planted in sites far from their natural provenance would be less adapted to local site conditions, leading to increased frost damage and reduced height growth; (b) at which height above the ground growing-season frosts ceased to damage apical meristems; and (c) if height growth was best predicted by extreme climatic events (growing-season frosts) or by mean annual or summer temperature. At each site and for all spruce species and seed sources, we cross-sectioned spruce trees at different heights above the ground. Tree rings were cross-dated and screened for frost rings, which were then given a severity score based on cellular damage. Frost severity reduced height growth of all spruce species and provenances at both sites. Height growth of the non-native Norway spruce was the most reduced by frost severity and was the smallest species at both sites. Frost caused the highest growth reduction in white spruce at the boreal mixedwood site and had the least effect on black spruce at both sites. For all spruce species, height growth was affected up to 2 m above the ground. Model selection based on corrected Akaike's information criteria (AICc) identified that minimum temperature in May was by far the best climate variable predicting tree growth (AICc weight = 1), highlighting the importance of considering extreme climatic events, which are likely to increase in the future.Increase in frost damage to trees due to earlier spring dehardening could outweigh the expected increase in forest productivity caused by climate warming. We quantified the impact of growing-season frosts on the performance of three spruce species (white, black, and Norway spruce) and various seed sources with different frost tolerance in two plantations, established on both sides of the eastern Canadian boreal-temperate forest ecotone. The objectives of this study were to determine (a) if spruce species and seed sources planted in sites far from their natural provenance would be less adapted to local site conditions, leading to increased frost damage and reduced height growth; (b) at which height above the ground growing-season frosts ceased to damage apical meristems; and (c) if height growth was best predicted by extreme climatic events (growing-season frosts) or by mean annual or summer temperature. At each site and for all spruce species and seed sources, we cross-sectioned spruce trees at different heights above the ground. Tree rings were cross-dated and screened for frost rings, which were then given a severity score based on cellular damage. Frost severity reduced height growth of all spruce species and provenances at both sites. Height growth of the non-native Norway spruce was the most reduced by frost severity and was the smallest species at both sites. Frost caused the highest growth reduction in white spruce at the boreal mixedwood site and had the least effect on black spruce at both sites. For all spruce species, height growth was affected up to 2 m above the ground. Model selection based on corrected Akaike's information criteria (AICc) identified that minimum temperature in May was by far the best climate variable predicting tree growth (AICc weight = 1), highlighting the importance of considering extreme climatic events, which are likely to increase in the future.
Increase in frost damage to trees due to earlier spring dehardening could outweigh the expected increase in forest productivity caused by climate warming. We quantified the impact of growing‐season frosts on the performance of three spruce species (white, black, and Norway spruce) and various seed sources with different frost tolerance in two plantations, established on both sides of the eastern Canadian boreal‐temperate forest ecotone. The objectives of this study were to determine (a) if spruce species and seed sources planted in sites far from their natural provenance would be less adapted to local site conditions, leading to increased frost damage and reduced height growth; (b) at which height above the ground growing‐season frosts ceased to damage apical meristems; and (c) if height growth was best predicted by extreme climatic events (growing‐season frosts) or by mean annual or summer temperature. At each site and for all spruce species and seed sources, we cross‐sectioned spruce trees at different heights above the ground. Tree rings were cross‐dated and screened for frost rings, which were then given a severity score based on cellular damage. Frost severity reduced height growth of all spruce species and provenances at both sites. Height growth of the non‐native Norway spruce was the most reduced by frost severity and was the smallest species at both sites. Frost caused the highest growth reduction in white spruce at the boreal mixedwood site and had the least effect on black spruce at both sites. For all spruce species, height growth was affected up to 2 m above the ground. Model selection based on corrected Akaike's information criteria (AICc) identified that minimum temperature in May was by far the best climate variable predicting tree growth (AICc weight = 1), highlighting the importance of considering extreme climatic events, which are likely to increase in the future. Growing‐season frosts reduce spruce height growth and more importantly affects white spruce compared to black spruce in plantations at the boreal‐temperate forest ecotone of western Québec. Growing‐season frosts also better predict tree height increment compared to more conventional climate variables such as mean annual temperature and mean summer temperature.
Author Tremblay, Francine
Marquis, Benjamin
Simard, Martin
Bergeron, Yves
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  surname: Marquis
  fullname: Marquis, Benjamin
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  organization: Université du Québec en Abitibi Témiscamingue
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  surname: Bergeron
  fullname: Bergeron, Yves
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  surname: Simard
  fullname: Simard, Martin
  organization: Laval University
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  givenname: Francine
  surname: Tremblay
  fullname: Tremblay, Francine
  organization: Université du Québec en Abitibi Témiscamingue
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Cites_doi 10.5558/tfc85453-3
10.1111/1365-2435.12309
10.1139/b66-103
10.1111/nph.12647
10.1016/j.ijmedinf.2018.05.006
10.3389/fpls.2016.01450
10.1093/treephys/23.13.931
10.1139/a11-017
10.1175/1520-0442(2001)014<1959:CODAET>2.0.CO;2
10.1038/s41467-018-05705-4
10.1016/j.foreco.2014.10.029
10.1016/j.rse.2018.04.003
10.1111/nph.14698
10.2307/2963479
10.2307/2403090
10.1111/j.1365-2486.2012.02712.x
10.1016/S0168-1923(97)00021-X
10.1139/x11-136
10.1038/416389a
10.5849/jof.16-039
10.1016/S0378-1127(01)00754-X
10.1002/2013EO200001
10.1641/B580311
10.1139/x03-224
10.1038/s41598-018-27893-1
10.1139/cjfr-2014-0282
10.1016/j.foreco.2014.07.013
10.1139/x96-158
10.5558/tfc2011-029
10.3159/07-RP-035R.1
10.1016/j.scib.2017.04.025
10.3389/fpls.2020.01031
10.1007/978-0-387-87458-6
10.1023/A:1012525626267
10.1139/X06-235
10.1111/j.1365-2435.2009.01587.x
10.1111/j.1365-3040.2012.02552.x
10.1111/gcb.14479
10.1139/X10-129
10.1139/x26-172
10.1023/A:1014442705845
10.1111/gcb.14619
10.1038/nature08649
10.1111/mec.12067
10.1111/1365-2745.12574
10.1038/s41467-017-02690-y
10.1007/s00265-010-1029-6
10.1016/j.foreco.2018.02.043
10.1093/forestry/66.1.27
10.1073/pnas.0807754105
10.1080/07352689.2014.858956
10.1002/ece3.3476
10.1007/978-94-017-7549-6
10.1016/j.agrformet.2005.12.011
10.1016/j.rse.2018.09.026
10.3389/fpls.2019.00306
10.1038/s41467-018-04039-5
10.1111/j.1365-2486.2009.01990.x
10.1111/j.1365-2486.2008.01735.x
10.1016/0002-1571(76)90010-8
10.1029/2009GL041849
10.1139/x26-165
10.1139/x72-013
10.1002/ece3.4920
10.1016/0168-1923(87)90050-5
10.5558/tfc85885-6
10.1007/s00484-019-01710-4
10.18637/jss.v067.i01
10.1016/S0378-1127(00)00331-5
10.1038/nature01286
10.1029/2006GB002888
10.1111/gcb.12470
10.1016/j.foreco.2004.10.045
10.1111/jbi.12238
10.1006/jtbi.2000.2178
10.1111/1365-2435.12623
10.3389/fpls.2017.01354
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Issue 11
Keywords growing-season frosts
sustainable forest management
boreal forest
tree dormancy
forest productivity
frost rings
stem analysis
Picea
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References 2017; 7
2017; 8
2010; 16
2009; 85
2001; 141
2013; 22
1997; 87
2019; 10
1993; 66
1975
2016; 30
2013; 202
2012; 18
2008; 105
2016; 104
2020; 11
2014; 28
2014; 330
2006; 137
2011; 19
2017; 115
2007; 37
2014; 20
2018; 9
2018; 8
1987; 40
2000; 14
2015; 336
2019; 63
2013; 94
2018; 211
2004; 34
2000; 207
2019; 25
1987
2011; 65
2018; 219
2018; 417
2007; 21
1996; 26
2001; 51
2009; 15
1996; 66
2009; 23
2017; 62
2019; 9
2010; 37
2010
2002; 33
2008; 58
2009
1996
2007
1997; 27
2002; 416
2014; 41
2012; 35
2010; 40
2014; 44
1972; 2
2018; 25
2017; 216
2015; 67
2016; 7
2019e
2019d
2018; 116
2019c
2019b
1986; 23
2019a
2002; 168
2005; 205
2009; 462
2011; 41
2018
2011; 87
2016
2008; 135
2013
1976; 16
2003; 421
1966; 44
2014; 33
2003; 23
Allen M. R. (e_1_2_9_2_1) 2018
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Otis Prud'homme G. (e_1_2_9_68_1) 2017; 8
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e_1_2_9_90_1
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Environment Canada (e_1_2_9_29_1) 2019
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e_1_2_9_16_1
e_1_2_9_37_1
e_1_2_9_58_1
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Dugas C. (e_1_2_9_24_1) 1975
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Environment Canada (e_1_2_9_26_1) 2019
e_1_2_9_6_1
e_1_2_9_4_1
e_1_2_9_60_1
Oke T. R. (e_1_2_9_64_1) 1987
Saucier J. P. (e_1_2_9_85_1) 2009
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Schweingruber F. H. (e_1_2_9_86_1) 2007
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R Development Core Team (e_1_2_9_81_1) 2018
References_xml – volume: 2
  start-page: 62
  year: 1972
  end-page: 63
  article-title: Frost damage to white spruce buds
  publication-title: Canadian Journal of Forest Research
– volume: 41
  start-page: 773
  year: 2014
  end-page: 783
  article-title: Spring frost and growing season length co‐control the cold range limits of broad‐leaved trees
  publication-title: Journal of Biogeography
– year: 2009
– volume: 40
  start-page: 1815
  year: 2010
  end-page: 1820
  article-title: Effects of thermal model and base temperature on estimates of thermal time to bud break in white spruce seedlings
  publication-title: Canadian Journal of Forest Research
– volume: 37
  start-page: 492
  year: 2007
  end-page: 504
  article-title: Frost hollows of the boreal forest as extreme environments for black spruce tree growth
  publication-title: Canadian Journal of Forest Research
– volume: 16
  start-page: 711
  year: 2010
  end-page: 731
  article-title: Radial growth response of four dominant boreal tree species to climate along a latitudinal gradient in the eastern Canadian boreal forest
  publication-title: Global Change Biology
– volume: 66
  start-page: 1
  year: 1996
  end-page: 43
  article-title: Forest models defined by field measurements: Estimation, error analysis and dynamics
  publication-title: Ecological Monographs
– volume: 34
  start-page: 531
  year: 2004
  end-page: 545
  article-title: Multivariate patterns of adaptive genetic variation and seed source transfer in
  publication-title: Canadian Journal of Forest Research
– volume: 44
  start-page: 879
  year: 1966
  end-page: 886
  article-title: Frost ring formation in stems of some conifer species
  publication-title: Canadian Journal of Botany
– volume: 23
  start-page: 1031
  year: 2009
  end-page: 1039
  article-title: Spring 2007 warmth and frost: Phenology, damage and refoliation in a temperate deciduous forest
  publication-title: Functional Ecology
– volume: 85
  start-page: 453
  year: 2009
  end-page: 462
  article-title: A case of severe frost damage prior to budbreak in young conifers in Northeastern Ontario: Consequence of climate change?
  publication-title: The Forestry Chronicle
– volume: 26
  start-page: 1481
  year: 1996
  end-page: 1489
  article-title: Freezing temperatures and exposure times during bud break and shoot elongation influence survival and growth of containerized black spruce ( ) seedlings
  publication-title: Canadian Journal of Forest Research
– volume: 9
  start-page: 2242
  year: 2019
  end-page: 2254
  article-title: Age‐mediation of tree‐growth responses to experimental warming in the northeastern Tibetan Plateau
  publication-title: Ecology and Evolution
– volume: 141
  start-page: 223
  year: 2001
  end-page: 235
  article-title: Frost damage to planted Norway spruce seedlings – Influence of site preparation and seedling type
  publication-title: Forest Ecology and Management
– volume: 21
  start-page: GB3018
  year: 2007
  article-title: Growing season extension and its impact on terrestrial carbon cycle in the Northern Hemisphere over the past 2 decades
  publication-title: Global Biogeochemical Cycles
– volume: 63
  start-page: 963
  year: 2019
  end-page: 972
  article-title: Frost controls spring phenology of juvenile Smith fir along elevational gradients on the southeastern Tibetan Plateau
  publication-title: International Journal of Biometeorology
– volume: 116
  start-page: 10
  year: 2018
  end-page: 17
  article-title: Comparison of variable selection methods for clinical predictive modeling
  publication-title: International Journal of Medical Informatics
– volume: 27
  start-page: 199
  year: 1997
  end-page: 206
  article-title: Patterns of adaptive genetic variation in eastern white pine ( ) from Quebec
  publication-title: Canadian Journal of Forest Research
– volume: 115
  start-page: 167
  year: 2017
  end-page: 178
  article-title: Adaptive silviculture for climate change: A national experiment in manager‐scientist partnerships to apply an adaptation framework
  publication-title: Journal of Forestry
– volume: 135
  start-page: 126
  year: 2008
  end-page: 146
  article-title: Plant phenology and distribution in relation to recent climate change
  publication-title: The Journal of the Torrey Botanical Society
– volume: 16
  start-page: 425
  year: 1976
  end-page: 443
  article-title: Estimating minimum temperature and climatological freeze risk in hilly terrain
  publication-title: Agricultural and Forest Meteorology
– volume: 67
  start-page: 1
  year: 2015
  end-page: 48
  article-title: Fitting linear mixed‐effects models using lme4
  publication-title: Journal of Statistical Software
– year: 2019e
– volume: 18
  start-page: 2365
  year: 2012
  end-page: 2377
  article-title: Ecological impacts of a widespread frost event following early spring leaf‐out
  publication-title: Global Change Biology
– year: 2019a
– volume: 87
  start-page: 139
  year: 1997
  end-page: 153
  article-title: Spatial and temporal variability of nocturnal summer frost in elevated complex terrain
  publication-title: Agricultural and Forest Meteorology
– year: 2018
– volume: 14
  start-page: 1959
  year: 2000
  end-page: 1976
  article-title: Characteristics of daily and extreme temperatures over Canada
  publication-title: Journal of Climate
– volume: 30
  start-page: 1480
  year: 2016
  end-page: 1490
  article-title: Convergence of leaf‐out towards minimum risk of freezing damage in temperate trees
  publication-title: Functional Ecology
– volume: 211
  start-page: 59
  year: 2018
  end-page: 70
  article-title: Capturing agricultural soil freeze/thaw state through remote sensing and ground observations: A soil freeze/thaw validation campaign
  publication-title: Remote Sensing of Environment
– start-page: 186
  year: 2009
  end-page: 205
– volume: 65
  start-page: 23
  year: 2011
  end-page: 35
  article-title: AIC model selection and multimodel inference in behavioral ecology: Some background, observations and comparisons
  publication-title: Behavioral Ecology and Sociobiology
– volume: 8
  start-page: 1354
  year: 2017
  article-title: Insufficient chilling effects vary among boreal tree species and chilling duration
  publication-title: Frontiers in Plant Science
– volume: 7
  start-page: 9954
  year: 2017
  end-page: 9969
  article-title: Trends and uncertainties in budburst projections of Norway spruce in Northern Europe
  publication-title: Ecology and Evolution
– volume: 205
  start-page: 169
  year: 2005
  end-page: 182
  article-title: The impact of climate change on growth of local white spruce populations in Québec, Canada
  publication-title: Forest Ecology and Management
– volume: 168
  start-page: 149
  year: 2002
  end-page: 161
  article-title: Effect of shelterwood density on nocturnal near‐ground temperature, frost injury risk and budburst date of Norway spruce
  publication-title: Forest Ecology and Management
– volume: 330
  start-page: 144
  year: 2014
  end-page: 157
  article-title: Effects of topography and thickness of organic layer on productivity of black spruce boreal forests of the Canadian Clay Belt region
  publication-title: Forest Ecology and Management
– volume: 15
  start-page: 961
  year: 2009
  end-page: 975
  article-title: Leaf phenology in 22 North American tree species during the 21st century
  publication-title: Global Change Biology
– volume: 85
  start-page: 885
  year: 2009
  end-page: 896
  article-title: TRIAD zoning in Quebec: Experiences and results after 5 years
  publication-title: Forestry Chronicle
– volume: 336
  start-page: 217
  year: 2015
  end-page: 223
  article-title: Vegetative buds, needles and shoot growth of Norway spruce are affected by experimentally delayed soil thawing in the field
  publication-title: Forest Ecology and Management
– volume: 10
  start-page: 306
  year: 2019
  article-title: Limitations at the limit? Diminishing of genetic effects in Norway spruce provenance trials
  publication-title: Frontiers in Plant Science
– year: 2019b
– volume: 33
  start-page: 73
  year: 2002
  end-page: 79
  article-title: Formation of two xylem frost injuries in one annual ring in Siberian spruce under conditions of Western Siberian forest‐tundra
  publication-title: Russian Journal of Ecology
– volume: 9
  start-page: 426
  year: 2018
  article-title: Extension of the growing season increases vegetation exposure to frost
  publication-title: Nature Communication
– volume: 137
  start-page: 15
  year: 2006
  end-page: 24
  article-title: Minimum temperature mapping over complex terrain by estimating cold air accumulation potential
  publication-title: Agricultural and Forest Meteorology
– volume: 40
  start-page: 1
  year: 1987
  end-page: 16
  article-title: Frost hazard assessment from local weather and terrain data
  publication-title: Agricultural and Forest Meteorology
– volume: 417
  start-page: 167
  year: 2018
  end-page: 183
  article-title: Tamm review: The North‐American lichen woodland
  publication-title: Forest Ecology and Management
– volume: 33
  start-page: 251
  year: 2014
  end-page: 285
  article-title: Can boreal and temperate forest management be adapted to the uncertainties of 21st century climate change?
  publication-title: Critical Reviews in Plant Sciences
– volume: 94
  start-page: 181
  year: 2013
  end-page: 188
  article-title: The false spring of 2012, earliest in North American record
  publication-title: Eos, Transactions, American Geophysical Union
– volume: 23
  start-page: 177
  year: 1986
  end-page: 191
  article-title: Climatic warming, spring budburst and forest damage on trees
  publication-title: Journal of Applied Ecology
– volume: 19
  start-page: 461
  year: 2011
  end-page: 478
  article-title: Ecology and management of natural regeneration of white spruce in the boreal forest
  publication-title: Environmental Review
– year: 1987
– year: 2007
– volume: 66
  start-page: 27
  year: 1993
  end-page: 36
  article-title: Shading reduces both visible and invisible frost damage to Norway spruce seedlings in the field
  publication-title: Forestry
– volume: 216
  start-page: 113
  year: 2017
  end-page: 123
  article-title: Frost hardening and dehardening potential in temperate trees from winter to budburst
  publication-title: New Phytologist
– volume: 28
  start-page: 1344
  year: 2014
  end-page: 1355
  article-title: Tree phenology responses to winter chilling, spring warming, at north and south range limits
  publication-title: Functional Ecology
– year: 1996
– volume: 20
  start-page: 2261
  year: 2014
  end-page: 2271
  article-title: Lengthening of the duration of xylogenesis engenders disproportionate increases in xylem production
  publication-title: Global Change Biology
– volume: 51
  start-page: 259
  year: 2001
  end-page: 305
  article-title: A review of forest gap models
  publication-title: Climatic Change
– volume: 35
  start-page: 1707
  year: 2012
  end-page: 1728
  article-title: The dynamic nature of bud dormancy in trees: Environmental control and molecular mechanisms
  publication-title: Plant, Cell and Environment
– volume: 41
  start-page: 2292
  year: 2011
  end-page: 2300
  article-title: Seedling growth and water use of boreal conifers across different temperatures and near‐flooded soil conditions
  publication-title: Canadian Journal of Forest Research
– year: 2019c
– volume: 9
  start-page: 1574
  year: 2018
  article-title: Cold adaptation recorded in tree rings highlights risks associated with climate change and assisted migration
  publication-title: Nature Communication
– year: 2016
– volume: 219
  start-page: 99
  year: 2018
  end-page: 114
  article-title: Fine‐scale three‐dimensional modeling of boreal forest plots to improve forest characterization with remote sensing
  publication-title: Remote Sensing of Environment
– volume: 23
  start-page: 931
  year: 2003
  end-page: 936
  article-title: High autumn temperature delays spring bud burst in boreal trees, counterbalancing the effect of climatic warming
  publication-title: Tree Physiology
– volume: 87
  start-page: 391
  year: 2011
  end-page: 397
  article-title: Assessment of assisted migration effects on spring bud flush in white spruce ( [Moench] Voss) seedlings
  publication-title: Forestry Chronicle
– volume: 421
  start-page: 37
  year: 2003
  end-page: 42
  article-title: A globally coherent fingerprint of climate change impacts across natural systems
  publication-title: Nature
– volume: 104
  start-page: 1076
  issue: 4
  year: 2016
  end-page: 1088
  article-title: Where, why and how? Explaining the low‐temperature range limits of temperate tree species
  publication-title: Journal of Ecology
– volume: 462
  start-page: 1052
  year: 2009
  end-page: 1055
  article-title: The velocity of climate change
  publication-title: Nature
– volume: 25
  start-page: 1922
  year: 2019
  end-page: 1940
  article-title: Plant phenology and global climate change: Current progresses and challenges
  publication-title: Global Change Biology
– year: 2010
– volume: 11
  start-page: 1031
  year: 2020
  article-title: Probability of spring frosts, not growing degree‐days, drives onset of spruce bud burst in plantations at the boreal‐temperate forest ecotone
  publication-title: Frontiers in Plant Science
– volume: 44
  start-page: 1555
  year: 2014
  end-page: 1565
  article-title: Will tree species experience increased frost damage due to climate change because of changes in leaf phenology?
  publication-title: Canadian Journal of Forest Research
– volume: 58
  start-page: 253
  year: 2008
  end-page: 262
  article-title: The 2007 eastern US spring freezing: Increased cold damage in a warming world
  publication-title: BioScience
– volume: 7
  year: 2016
  article-title: Morpho‐physiological variation of white spruce seedlings from various seed sources and implications for deployment under climate change
  publication-title: Frontiers in Plant Science
– volume: 9
  start-page: 3213
  year: 2018
  article-title: Beneficial effects of climate warming on boreal tree growth may be transitory
  publication-title: Nature Communication
– volume: 8
  year: 2017
  article-title: Ecophysiology and growth of white spruce seedlings from various seed sources along a climatic gradient support the need for assisted migration
  publication-title: Frontiers in Plant Science
– volume: 207
  start-page: 337
  year: 2000
  end-page: 347
  article-title: A unified model for budburst of trees
  publication-title: Journal of Theoretical Biology
– volume: 26
  start-page: 1531
  year: 1996
  end-page: 1538
  article-title: Influence of shelter on night temperatures, frost damage, and bud break of white spruce seedlings
  publication-title: Canadian Journal of Forest Research
– volume: 37
  start-page: L02711
  year: 2010
  article-title: Frost‐ring chronologies as dendroclimatic proxies of boreal environments
  publication-title: Geophysical Research Letters
– volume: 416
  start-page: 389
  year: 2002
  end-page: 395
  article-title: Ecological responses to recent climate change
  publication-title: Nature
– volume: 8
  start-page: 9865
  year: 2018
  article-title: Climate‐induced shifts in leaf unfolding and frost risk of European trees and shrubs
  publication-title: Scientific Reports
– volume: 25
  start-page: 351
  year: 2018
  end-page: 360
  article-title: Divergent trends in the risk of spring frost damage to trees in Europe with recent warming
  publication-title: Global Change Biology
– start-page: 140
  year: 1975
– year: 2019d
– volume: 105
  start-page: 17018
  year: 2008
  end-page: 17022
  article-title: Predicting and understanding forest dynamics using a simple tractable model
  publication-title: Proceedings of the National Academy of Science of the United States of America
– volume: 22
  start-page: 1214
  year: 2013
  end-page: 1230
  article-title: The adaptive potential of L. to phenology requirements in a warmer global climate
  publication-title: Molecular Ecology
– volume: 202
  start-page: 106
  year: 2013
  end-page: 115
  article-title: Drivers of leaf‐out phenology and their implications for species invasions: Insights from Thoreau's Concord
  publication-title: New Phytologist
– volume: 62
  start-page: 804
  year: 2017
  end-page: 812
  article-title: Critical minimum temperature limits xylogenesis and maintains treelines on the southeastern Tibetan Plateau
  publication-title: Science Bulletin
– year: 2018
  article-title: Parameterization of freeze/thaw discrimination function algorithm using dense observation network data
  publication-title: International Journal of Digital Earth
– year: 2013
– ident: e_1_2_9_55_1
  doi: 10.5558/tfc85453-3
– ident: e_1_2_9_18_1
  doi: 10.1111/1365-2435.12309
– ident: e_1_2_9_32_1
  doi: 10.1139/b66-103
– ident: e_1_2_9_76_1
  doi: 10.1111/nph.12647
– ident: e_1_2_9_84_1
  doi: 10.1016/j.ijmedinf.2018.05.006
– ident: e_1_2_9_88_1
  doi: 10.3389/fpls.2016.01450
– ident: e_1_2_9_37_1
  doi: 10.1093/treephys/23.13.931
– volume-title: Wood structure and environment
  year: 2007
  ident: e_1_2_9_86_1
– ident: e_1_2_9_31_1
  doi: 10.1139/a11-017
– ident: e_1_2_9_78_1
– ident: e_1_2_9_11_1
  doi: 10.1175/1520-0442(2001)014<1959:CODAET>2.0.CO;2
– ident: e_1_2_9_22_1
  doi: 10.1038/s41467-018-05705-4
– ident: e_1_2_9_87_1
  doi: 10.1016/j.foreco.2014.10.029
– ident: e_1_2_9_83_1
  doi: 10.1016/j.rse.2018.04.003
– ident: e_1_2_9_89_1
  doi: 10.1111/nph.14698
– volume-title: Earlton weather station
  year: 2019
  ident: e_1_2_9_29_1
– ident: e_1_2_9_69_1
  doi: 10.2307/2963479
– start-page: 186
  volume-title: Manuel de foresterie
  year: 2009
  ident: e_1_2_9_85_1
– volume-title: Boundary layer climates
  year: 1987
  ident: e_1_2_9_64_1
– volume-title: Création des courbes d'évolution. Calcul des possibilités forestières 2013–2018
  year: 2013
  ident: e_1_2_9_77_1
– ident: e_1_2_9_15_1
  doi: 10.2307/2403090
– ident: e_1_2_9_39_1
  doi: 10.1111/j.1365-2486.2012.02712.x
– ident: e_1_2_9_50_1
  doi: 10.1016/S0168-1923(97)00021-X
– year: 2018
  ident: e_1_2_9_91_1
  article-title: Parameterization of freeze/thaw discrimination function algorithm using dense in‐situ observation network data
  publication-title: International Journal of Digital Earth
– ident: e_1_2_9_93_1
  doi: 10.1139/x11-136
– ident: e_1_2_9_90_1
  doi: 10.1038/416389a
– ident: e_1_2_9_63_1
  doi: 10.5849/jof.16-039
– ident: e_1_2_9_44_1
  doi: 10.1016/S0378-1127(01)00754-X
– ident: e_1_2_9_5_1
  doi: 10.1002/2013EO200001
– ident: e_1_2_9_34_1
  doi: 10.1641/B580311
– ident: e_1_2_9_7_1
  doi: 10.1139/x03-224
– ident: e_1_2_9_9_1
  doi: 10.1038/s41598-018-27893-1
– ident: e_1_2_9_61_1
  doi: 10.1139/cjfr-2014-0282
– volume-title: Global warming of 1.5°C
  year: 2018
  ident: e_1_2_9_2_1
– ident: e_1_2_9_43_1
  doi: 10.1016/j.foreco.2014.07.013
– ident: e_1_2_9_48_1
  doi: 10.1139/x96-158
– ident: e_1_2_9_53_1
  doi: 10.5558/tfc2011-029
– ident: e_1_2_9_8_1
  doi: 10.3159/07-RP-035R.1
– ident: e_1_2_9_49_1
  doi: 10.1016/j.scib.2017.04.025
– ident: e_1_2_9_58_1
  doi: 10.3389/fpls.2020.01031
– volume: 8
  year: 2017
  ident: e_1_2_9_68_1
  article-title: Ecophysiology and growth of white spruce seedlings from various seed sources along a climatic gradient support the need for assisted migration
  publication-title: Frontiers in Plant Science
– ident: e_1_2_9_94_1
  doi: 10.1007/978-0-387-87458-6
– ident: e_1_2_9_13_1
  doi: 10.1023/A:1012525626267
– ident: e_1_2_9_25_1
  doi: 10.1139/X06-235
– ident: e_1_2_9_79_1
– ident: e_1_2_9_4_1
  doi: 10.1111/j.1365-2435.2009.01587.x
– volume-title: Mont‐Brun weather station, normal 1981–2010
  year: 2019
  ident: e_1_2_9_27_1
– ident: e_1_2_9_20_1
  doi: 10.1111/j.1365-3040.2012.02552.x
– ident: e_1_2_9_54_1
  doi: 10.1111/gcb.14479
– ident: e_1_2_9_56_1
  doi: 10.1139/X10-129
– ident: e_1_2_9_33_1
  doi: 10.1139/x26-172
– ident: e_1_2_9_35_1
  doi: 10.1023/A:1014442705845
– volume-title: R: A language and environment for statistical computing
  year: 2018
  ident: e_1_2_9_81_1
– ident: e_1_2_9_75_1
  doi: 10.1111/gcb.14619
– ident: e_1_2_9_52_1
  doi: 10.1038/nature08649
– ident: e_1_2_9_65_1
  doi: 10.1111/mec.12067
– ident: e_1_2_9_42_1
  doi: 10.1111/1365-2745.12574
– ident: e_1_2_9_51_1
  doi: 10.1038/s41467-017-02690-y
– ident: e_1_2_9_14_1
  doi: 10.1007/s00265-010-1029-6
– ident: e_1_2_9_72_1
  doi: 10.1016/j.foreco.2018.02.043
– ident: e_1_2_9_67_1
  doi: 10.1093/forestry/66.1.27
– ident: e_1_2_9_80_1
  doi: 10.1073/pnas.0807754105
– ident: e_1_2_9_70_1
  doi: 10.1080/07352689.2014.858956
– start-page: 140
  volume-title: Le climat et son influence sur l'agriculture abitibienne. Sud de la baie de James et partie de l'enclave argileuse de l'Objibway. Collection Nordicana
  year: 1975
  ident: e_1_2_9_24_1
– ident: e_1_2_9_66_1
  doi: 10.1002/ece3.3476
– ident: e_1_2_9_36_1
  doi: 10.1007/978-94-017-7549-6
– ident: e_1_2_9_17_1
  doi: 10.1016/j.agrformet.2005.12.011
– ident: e_1_2_9_21_1
  doi: 10.1016/j.rse.2018.09.026
– ident: e_1_2_9_40_1
  doi: 10.3389/fpls.2019.00306
– ident: e_1_2_9_60_1
  doi: 10.1038/s41467-018-04039-5
– ident: e_1_2_9_38_1
  doi: 10.1111/j.1365-2486.2009.01990.x
– ident: e_1_2_9_62_1
  doi: 10.1111/j.1365-2486.2008.01735.x
– ident: e_1_2_9_12_1
  doi: 10.1016/0002-1571(76)90010-8
– ident: e_1_2_9_73_1
  doi: 10.1029/2009GL041849
– ident: e_1_2_9_10_1
  doi: 10.1139/x26-165
– ident: e_1_2_9_19_1
  doi: 10.1139/x72-013
– ident: e_1_2_9_23_1
  doi: 10.1002/ece3.4920
– ident: e_1_2_9_46_1
  doi: 10.1016/0168-1923(87)90050-5
– ident: e_1_2_9_59_1
  doi: 10.5558/tfc85885-6
– ident: e_1_2_9_92_1
  doi: 10.1007/s00484-019-01710-4
– ident: e_1_2_9_6_1
  doi: 10.18637/jss.v067.i01
– ident: e_1_2_9_45_1
  doi: 10.1016/S0378-1127(00)00331-5
– ident: e_1_2_9_71_1
  doi: 10.1038/nature01286
– ident: e_1_2_9_74_1
  doi: 10.1029/2006GB002888
– ident: e_1_2_9_82_1
  doi: 10.1111/gcb.12470
– ident: e_1_2_9_3_1
  doi: 10.1016/j.foreco.2004.10.045
– volume-title: Sunset calculator
  year: 2019
  ident: e_1_2_9_28_1
– ident: e_1_2_9_41_1
  doi: 10.1111/jbi.12238
– ident: e_1_2_9_16_1
  doi: 10.1006/jtbi.2000.2178
– volume-title: Barrage Angliers weather station, normal 1981–2010
  year: 2019
  ident: e_1_2_9_26_1
– ident: e_1_2_9_47_1
  doi: 10.1111/1365-2435.12623
– volume-title: Rouyn A weather station
  year: 2019
  ident: e_1_2_9_30_1
– ident: e_1_2_9_57_1
  doi: 10.3389/fpls.2017.01354
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Snippet Increase in frost damage to trees due to earlier spring dehardening could outweigh the expected increase in forest productivity caused by climate warming. We...
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SubjectTerms Annual
apical meristems
boreal forest
Boreal forests
Canada
Climate
Climate change
Climate prediction
ecotones
Forest productivity
Forests
Frost
Frost damage
frost injury
frost resistance
frost rings
Global warming
Growing season
growing‐season frosts
Growth
growth retardation
Habitat selection
Height
Meristems
Norway
Picea
Picea abies
Picea glauca
Picea mariana
Pine trees
Plantations
provenance
Seasons
Species
stem analysis
summer
sustainable forest management
Temperate forests
Temperature
tree dormancy
tree growth
Tree rings
Trees
Title Growing‐season frost is a better predictor of tree growth than mean annual temperature in boreal mixedwood forest plantations
URI https://onlinelibrary.wiley.com/doi/abs/10.1111%2Fgcb.15327
https://www.ncbi.nlm.nih.gov/pubmed/32865303
https://www.proquest.com/docview/2451742599
https://www.proquest.com/docview/2438995511
https://www.proquest.com/docview/2551977626
Volume 26
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