Dan Binkley

Forest Ecology


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USA grades from primarily grass/shrub domination at low, dry elevations, through open pine-dominated woodlands, to aspens mixed with a variety of conifers, to forests of spruce and fir and then to tundra (alpine) at the highest elevations."/>

      (Source: based on a diagram from Laurie Huckaby).

      The patterns depend on direct effects of environmental factors on tree physiology, and also environmental influences on fires, insects, and other forest‐shaping agents.

Schematic illustration of the distributions of major types of forests can be mapped across the world (upper), along with typical rates of aboveground net primary production of forests and other vegetation types.

      Source: maps based on Pan et al. 2013).

      The spatial patterns can also be examined in a functional way, where aboveground net primary production is plotted relative to annual temperatures, and the balance between precipitation and the energy available to evaporate water (wetter conditions occur above the 0 point on the Y‐axis;

      Source: Based on Running et al. 2004.

Schematic illustration of the tallest trees in the world occur in cool, wet locations, and most tall trees are limited to relatively wet areas.

      (Source: upper map, from Pan et al. 2013/Annual reviews,Inc.).

      The diversity of tree species in a tropical forest in Costa Rica dropped by about half with a 1000 m increase in elevation (lower left,

      Source: Data from Veintimilla et al. 2019, photo by Cristian Montes).

      Across eastern China, the number of tree species that co‐occur in 600 m2 (=0.06 ha) plots increases rapidly with temperature, but levels off (and might even decline) on the hottest sites.

      Source: Based on Wang et al. 2009.

      The temperature effect on more complex biochemical reaction rates includes any effects on the breakdown and regeneration rates of enzymes and other proteins. Biological reactions also change as temperatures affect the supplies of reactants. Higher temperatures lead to greater evaporative stresses, which reduce the supply rate of carbon dioxide flowing into leaves. The products of reactions can suppress rates of further reaction if they accumulate in cells, which can be a problem at high temperatures. Rates of photosynthesis do not increase with a simple exponential trend like rates of respiration (Figure 2.3). The temperature effect on rates of photosynthesis might have a humped shape, reflecting the balance between carbon gains and losses in leaves, as photosynthesis declines in response to rising photorespiration (the diversion of energy to producing water rather than sugar).

      The temperature of an object, such as a tree leaf, represents the thermal energy contained within the object. Thermal energy is the kinetic energy of molecules; the molecules of nitrogen in a volume of air move at velocities of about 450 to 500 m per second. A molecule of nitrogen might move about 100 nm before colliding with another air molecule, which translates into billions of collisions for each molecule each second. Molecules move faster as temperatures rise, leading to