© 1992 Heron Publishing—Victoria, Canada
Effects of radiational heating at low air temperature on water balance, cold tolerance, and visible injury of red spruce foliage
Julian L. Hadley and Robert G. Amundson
Boyce Thompson Institute for Plant Research, Cornell University, Tower Road, Ithaca, NY 14853, USA / Received August 14, 1991
Summary
Recent studies have shown that winter needle mortality in red spruce (Picea rubens Sarg.) is increased by exposure to direct solar radiation, possibly as a result of photo-oxidative damage, accelerated winter
desiccation, or reduced cold tolerance due to heating of sun-exposed needles. In an experiment at controlled subfreezing air
temperatures of –10 to –20 °C, visible radiation was less effective than infrared radiation in producing needle desiccation
and visible injury during freeze–thaw cycles. However, visible radiation produced a red-brown color in injured needles, similar
to natural winter injury, whereas injured needles exposed to infrared radiation were yellow and injured needles kept in darkness
were dark brown. Thus, visible radiation was necessary to produce the red-brown color of damaged needles, but not the injury
itself. Needle desiccation was not strongly correlated with visible injury, but the pattern of variation in visible injury
among trees and the positive correlation between electrolyte leakage and visible injury suggested that freezing damage following
freeze–thaw cycles might cause the visible injury. This was confirmed by a second experiment that showed loss of cold hardiness
in needles thawed by radiational heating for six consecutive days. Even with a constant nighttime temperature of –10 °C, six
days of radiational heating of needles to above freezing caused a small (2.8 °C) mean decrease in needle cold tolerance, as
measured by electrolyte leakage. Continuous darkness at –10 °C for six days resulted in an estimated 5.6 °C mean increase
in needle cold tolerance. Freezing injury stimulated desiccation: cooling at 4 °C h–1 to –43 or –48 °C increased the dehydration rate of isolated shoots by a factor of two to three during the first day after
thawing. Within three days at 15 to 22 °C and 50% relative humidity, the mean water content of these shoots fell to 60% or
lower, compared to 90% or greater for unfrozen controls or shoots subject to less severe freezing stress. In some but not
all severely freeze-stressed shoots, accelerated needle desiccation and abscission were accompanied by a red-brown color typical
of red spruce winter needle injury. We conclude that severe winter desiccation in red spruce may often be due to prior freezing
injury, increased as a result of exposure to direct solar radiation. Furthermore, freezing injury in red spruce may sometimes
cause desiccation and abscission of green needles.
