Premium
Time to chill: effects of simulated global change on leaf ice nucleation temperatures of subarctic vegetation
Author(s) -
Beerling D. J.,
Terry A. C.,
Mitchell P. L.,
Callaghan T. V.,
GwynnJones D.,
Lee J. A.
Publication year - 2001
Publication title -
american journal of botany
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 1.218
H-Index - 151
eISSN - 1537-2197
pISSN - 0002-9122
DOI - 10.2307/2657062
Subject(s) - subarctic climate , evergreen , deciduous , vegetation (pathology) , ice nucleus , growing season , biology , atmospheric sciences , botany , ecology , nucleation , geology , chemistry , medicine , organic chemistry , pathology
We investigated the effects of long‐term (7‐yr) in situ CO 2 enrichment (600 μmol/mol) and increased exposure to UV‐B radiation, the latter an important component of global change at high latitudes, on the ice nucleation temperatures of leaves of several evergreen and deciduous woody ericaceous shrubs in the subarctic (68° N). Three ( Vaccinium uliginosum, V. vitis‐idaea , and Empetrum hermaphroditum ) of the four species of shrubs studied showed significantly higher ice nucleation temperatures throughout the 1999 growing season in response to CO 2 enrichment and increased exposure to UV‐B radiation relative to the controls. The same species also showed a strong interactive effect when both treatments were applied together. In all cases, leaves cooled to below their ice nucleation temperatures failed to survive the damage resulting from intracellular ice formation. Our results strongly suggest that future global change on a decadal time scale (atmospheric CO 2 increases and polar stratospheric O 3 destruction) will lead to increased foliage damage of subarctic vegetation by severe late spring or early autumnal frosting events. Indeed, in support of our experimental findings, there is now some evidence that increases in atmospheric CO 2 concentration over the past three to four decades may already have acted in this manner on high‐elevation arboreal plants in the Swedish Scandes. The implications for vegetation modeling in a future “greenhouse” world and palaeoclimate estimates from high‐latitude plant fossils dating to the high‐CO 2 environment of the Mesozoic are discussed.