Note leaning limber pine emerging from large fissure in granite outcrop, near center of lower left quarter of photo (click on image for better view).
I’m following two trees. One is a weeping birch that grows in my yard, subject of a recent post. All summer long its leaves collected sunshine and carbon dioxide, cranking out carbohydrates to keep the birch healthy and growing. Then about a month ago, after turning a pretty gold, they died and fell off. Just as well ... thin flimsy birch leaves would freeze in winter. Now the tree is dormant.Weeping birch, Betula pendula, native to Europe and Asia.
My other tree is a limber pine (Pinus flexilis) in the Laramie Mountains east of town. It grows out of a deep fissure in a large outcrop of 1.4-billion-year-old Sherman granite. I went up there just last week to see what it’s doing. These are the perks of tree-following, going to nice places and seeing and learning things I probably wouldn’t otherwise. All the quaking aspen along the trail were bare. They got rid of their worthless leaves over a month ago.
Evergreen -- with leaves year-round; most conifers and many broadleaved trees.
Deciduous -- leafless part of the year when conditions are inhospitable to growth; a few conifers and many broadleaved trees.
Conifers -- Gymnosperms, with naked exposed seeds frequently in cones (no flowers); e.g. pine, spruce, Douglas fir, redwood. Leaves usually needle-shaped or scale-like, but sometimes broad. A more primitive group evolutionarily. Also called “softwoods”.
Broadleaved trees -- Angiosperms, with developing seeds housed inside ovaries in flowers; e.g. magnolia, maple, eucalyptus, beech, weeping birch. Leaves usually broader than needles but not always. A more advanced group evolutionarily. Also called “hardwoods”.
Below, a compact and durable conifer needle, followed by part of a thin flimsy but more productive broad leaf. Source (modified). Photosynthesis takes place in the mesophyll.
Limber pine needles are five to a cluster.
Turns out the limber pine has been getting ready for winter, for some time now. It went through a pre-dormancy stage as it does every year. Resting buds were formed, growth stopped, metabolism slowed, and various chemical changes took place -- for example increasing salts and sugars in cells to lower the freezing temperature. Now it can rest through the winter.Dormancy ends in spring after a sufficiently long period of sufficiently cold weather. It’s then that the benefit of keeping needles all winter becomes apparent. The limber pine won’t have to grow a whole new set of leaves, it can get to work photosynthesizing and making tree food right away!Some conifers even photosynthesize at low rates during warm spells in winter, another advantage of keeping needles on. Can a limber pine do this? I don’t know.
I'm following a tree ... are you?
Sources (in addition to links in post)Havranek, WM and Tranquillini, W. 1995. Physiological processes during winter dormancy in Smith, WK and Hinckley, TM, eds. Ecophysiology of coniferous forests. Academic Press.Thomas, P. 2000. Trees: their natural history. Cambridge University Press.