Dan Binkley

Forest Ecology


Скачать книгу

Molecules are packed more densely in liquids and solids, leading to higher rate of collisions (and transfers of heat).

Graphs depict the rates of chemical processes increase with increasing temperature, as reflected in the rising curve for respiration of trees in a rainforest in Costa Rica.

      (Source: Based on Cavaleri et al. 2010).

      The rate of total (gross) photosynthesis by fully illuminated leaves in a rainforest in Panama also rises with temperature to an optimum near 30 °C, and then declines

      (Source: Based on Slot and Winter 2017).

      The two graphs present the same data, with the upper graph focusing primarily on how each process responds to temperature, while the lower graph uses a single Y axis to give show how much larger photosynthesis is relative to respiration (across the temperature gradient).

      A leaf increases in thermal energy when exposed to radiant energy from the sun, and when exposed to hot air. Absorption of solar radiation raises leaf thermal energy, raising leaf temperature. The temperature of the leaf continues to rise until the gain of energy is offset by energy losses. Leaves can lose energy by exposure to cooler air, by evaporating water, and by emitting (shining) radiant energy.

A graph depicts the temperatures of leaves of beech and spruce were sustained at higher levels as a result of heating by sunlight.

      Source: Data from Leuzinger and Körner (2007).

      The evaporation of water requires large amounts of energy, about 2.4 MJ/l evaporated. This energy flow is referred to as “latent heat,” because the temperature of the water molecules remains unchanged as the phase changes from liquid to gas. The amount of energy removed from an object such as a leaf depends of course on the rate of evaporation, and rates of evaporation depend on the water status of the plant, the dryness of the air, and the presence of wind to reduce the boundary layer. Evaporation from a leaf exposed to dry air without any wind may lower leaf temperature by about a degree; the addition of a light wind can increase evaporation enough to cool leaves by 3–5 °C.

      Radiation from the sun can be felt by holding out a hand in bright sun; the hand absorbs the solar radiation and warms up. We can see the hand illuminated by sunlight, because some of the light reflects from the hand and reaches our eyes. Another radiation story is also occurring, invisible to our eyes. The hand is also “shining” like the sun, emitting radiation to the environment around it. The cooler temperature of the hand means the wavelengths of radiation emitted are much longer than sunlight (a long wavelength is the same as a low frequency). The emission of radiation by the hand removes energy, and would lead to cooling of the hand unless another source of energy kept the hand warm.

      The radiant energy emitted by the sun is called “shortwave” radiation, because of the short wavelengths (between about 400 and 700 nm for the visible portion of the solar spectrum). Objects at temperatures commonly encountered in forests “shine” or emit radiation at longer wavelengths, on the order of 10 μm. Longwave radiation may be sensed by skin as warmth, even though the weak radiation cannot be detected by our eyes.

Graph depicts that all objects emit radiation to the environment, and hotter objects emit more energy than cooler objects.

Graph depicts the total potential sunlight at 23° latitude (6100 W m-2 yr-1) is almost double </p>
						</div><hr>
						<div class= Скачать книгу