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Frost and leaf-size gradients in forests : global patterns and experimental evidence

Lusk, Christopher H. ; Clearwater, Michael J. ; Laughlin, Daniel C. ; Harrison, Sandy P. ; Prentice, Iain Colin LU ; Nordenstahl, Marisa and Smith, Benjamin LU (2018) In New Phytologist 219(2). p.565-573
Abstract

Explanations of leaf size variation commonly focus on water availability, yet leaf size also varies with latitude and elevation in environments where water is not strongly limiting. We provide the first conclusive test of a prediction of leaf energy balance theory that may explain this pattern: large leaves are more vulnerable to night-time chilling, because their thick boundary layers impede convective exchange with the surrounding air. Seedlings of 15 New Zealand evergreens spanning 12-fold variation in leaf width were exposed to clear night skies, and leaf temperatures were measured with thermocouples. We then used a global dataset to assess several climate variables as predictors of leaf size in forest assemblages. Leaf minus air... (More)

Explanations of leaf size variation commonly focus on water availability, yet leaf size also varies with latitude and elevation in environments where water is not strongly limiting. We provide the first conclusive test of a prediction of leaf energy balance theory that may explain this pattern: large leaves are more vulnerable to night-time chilling, because their thick boundary layers impede convective exchange with the surrounding air. Seedlings of 15 New Zealand evergreens spanning 12-fold variation in leaf width were exposed to clear night skies, and leaf temperatures were measured with thermocouples. We then used a global dataset to assess several climate variables as predictors of leaf size in forest assemblages. Leaf minus air temperature was strongly correlated with leaf width, ranging from −0.9 to −3.2°C in the smallest- and largest-leaved species, respectively. Mean annual temperature and frost-free period were good predictors of evergreen angiosperm leaf size in forest assemblages, but no climate variable predicted deciduous leaf size. Although winter deciduousness makes large leaves possible in strongly seasonal climates, large-leaved evergreens are largely confined to frost-free climates because of their susceptibility to radiative cooling. Evergreen leaf size data can therefore be used to enhance vegetation models, and to infer palaeotemperatures from fossil leaf assemblages.

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author
; ; ; ; ; and
organization
publishing date
type
Contribution to journal
publication status
published
subject
keywords
boundary layer, frost, latitudinal gradients, leaf energy balance theory, leaf habit, leaf width, New Zealand, night-time chilling
in
New Phytologist
volume
219
issue
2
pages
9 pages
publisher
Wiley-Blackwell
external identifiers
  • scopus:85048804792
  • pmid:29766502
ISSN
0028-646X
DOI
10.1111/nph.15202
language
English
LU publication?
yes
id
9d444312-b73e-41a8-9905-7180773c3e32
date added to LUP
2018-07-04 13:24:12
date last changed
2024-06-11 17:25:24
@article{9d444312-b73e-41a8-9905-7180773c3e32,
  abstract     = {{<p>Explanations of leaf size variation commonly focus on water availability, yet leaf size also varies with latitude and elevation in environments where water is not strongly limiting. We provide the first conclusive test of a prediction of leaf energy balance theory that may explain this pattern: large leaves are more vulnerable to night-time chilling, because their thick boundary layers impede convective exchange with the surrounding air. Seedlings of 15 New Zealand evergreens spanning 12-fold variation in leaf width were exposed to clear night skies, and leaf temperatures were measured with thermocouples. We then used a global dataset to assess several climate variables as predictors of leaf size in forest assemblages. Leaf minus air temperature was strongly correlated with leaf width, ranging from −0.9 to −3.2°C in the smallest- and largest-leaved species, respectively. Mean annual temperature and frost-free period were good predictors of evergreen angiosperm leaf size in forest assemblages, but no climate variable predicted deciduous leaf size. Although winter deciduousness makes large leaves possible in strongly seasonal climates, large-leaved evergreens are largely confined to frost-free climates because of their susceptibility to radiative cooling. Evergreen leaf size data can therefore be used to enhance vegetation models, and to infer palaeotemperatures from fossil leaf assemblages.</p>}},
  author       = {{Lusk, Christopher H. and Clearwater, Michael J. and Laughlin, Daniel C. and Harrison, Sandy P. and Prentice, Iain Colin and Nordenstahl, Marisa and Smith, Benjamin}},
  issn         = {{0028-646X}},
  keywords     = {{boundary layer; frost; latitudinal gradients; leaf energy balance theory; leaf habit; leaf width; New Zealand; night-time chilling}},
  language     = {{eng}},
  month        = {{07}},
  number       = {{2}},
  pages        = {{565--573}},
  publisher    = {{Wiley-Blackwell}},
  series       = {{New Phytologist}},
  title        = {{Frost and leaf-size gradients in forests : global patterns and experimental evidence}},
  url          = {{http://dx.doi.org/10.1111/nph.15202}},
  doi          = {{10.1111/nph.15202}},
  volume       = {{219}},
  year         = {{2018}},
}