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The influence of canopy structure an...

Pypker, Thomas G.

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The influence of canopy structure and epiphytes on the hydrology of Douglas-fir forests.

Record Type:	Electronic resources : Monograph/item
Title/Author:	The influence of canopy structure and epiphytes on the hydrology of Douglas-fir forests./
Author:	Pypker, Thomas G.
Description:	180 p.
Notes:	Source: Dissertation Abstracts International, Volume: 66-02, Section: B, page: 0634.
Contained By:	Dissertation Abstracts International66-02B.
Subject:	Agriculture, Forestry and Wildlife. -
Online resource:	http://pqdd.sinica.edu.tw/twdaoapp/servlet/advanced?query=3165862
ISBN:	9780542012822

The influence of canopy structure and epiphytes on the hydrology of Douglas-fir forests.
Pypker, Thomas G.

The influence of canopy structure and epiphytes on the hydrology of Douglas-fir forests. - 180 p.

Source: Dissertation Abstracts International, Volume: 66-02, Section: B, page: 0634.

Thesis (Ph.D.)--Oregon State University, 2005.

Canopy structure has a significant impact on the canopy hydrology of Douglas-fir forests in the Pacific Northwest (PNW). Whole canopy rainfall interception was measured for young Douglas-fir forest and compared to an old-growth Douglas-fir forest. The old-growth forest had significantly greater canopy water storage capacity (S) and direct throughfall fraction (p). However, the interception loss (In) for the old-growth forest was only slightly larger than the young forest due to the similar ratios of evaporation to rainfall intensity (E/R¯). The spatial distribution of throughfall was more right-skewed in the old-growth forest; with many locations receiving throughfall in excess of gross precipitation (PG). Despite differences in the spatial distribution of throughfall, the spatial distribution of soil moisture did not differ between the two forests. Because the S was significantly greater in the old-growth forest, the influence of epiphytic lichens and bryophytes on S was examined. The maximum water content (MWCx) of individual samples of fruticose lichens, foliose lichens, and bryophytes from an old-growth Douglas-fir forest were measured in the laboratory and the field. The laboratory results indicate that typical epiphytic fruticose lichens, foliose lichens and bryophytes for old-growth Douglas-fir forests in the PNW could store 2.23, 3.42 and 9.99 times their dry weight in water, respectively. Although these values could be used to predict the maximum epiphyte-laden branch water storage under laboratory conditions, they were unable to do so under field conditions. In the field the biomass on the branch could not predict the maximum branch water storage because the branches: (1) were partially saturated for most of the measurement period; and (2) required greater than 30 mm of rain to saturate due to preferential flow routing water through the epiphyte mats. The frequent storms and the slow saturation of the canopy resulted an underestimation of S and an overestimation of E/R¯ by standard regression based techniques for estimating canopy variables. Lastly, the water stored on epiphyte-laden branches after exposure to natural rainfall was positively associated with rainfall intensity. The absorption of atmospheric water vapor by epiphytes in old-growth Douglas-fir forests in the PNW may have facilitated carbon uptake by green lichens and altered the energy budget of the forest during the seasonal summer drought. During the summer months the green lichens absorb sufficient quantities of atmospheric water to reactivate their photosystems. The diurnal absorption/evaporation of atmospheric water will result in significant uptake of water at night and may account for 5 to 21% of the canopy latent heat flux in the early morning (600 to 1000 h).

ISBN: 9780542012822Subjects--Topical Terms:

783690
Agriculture, Forestry and Wildlife.

The influence of canopy structure and epiphytes on the hydrology of Douglas-fir forests.
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245 1 4 $a The influence of canopy structure and epiphytes on the hydrology of Douglas-fir forests.
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500 $a Adviser: Barbara J. Bond.
502 $a Thesis (Ph.D.)--Oregon State University, 2005.
520 $a Canopy structure has a significant impact on the canopy hydrology of Douglas-fir forests in the Pacific Northwest (PNW). Whole canopy rainfall interception was measured for young Douglas-fir forest and compared to an old-growth Douglas-fir forest. The old-growth forest had significantly greater canopy water storage capacity (S) and direct throughfall fraction (p). However, the interception loss (In) for the old-growth forest was only slightly larger than the young forest due to the similar ratios of evaporation to rainfall intensity (E/R¯). The spatial distribution of throughfall was more right-skewed in the old-growth forest; with many locations receiving throughfall in excess of gross precipitation (PG). Despite differences in the spatial distribution of throughfall, the spatial distribution of soil moisture did not differ between the two forests. Because the S was significantly greater in the old-growth forest, the influence of epiphytic lichens and bryophytes on S was examined. The maximum water content (MWCx) of individual samples of fruticose lichens, foliose lichens, and bryophytes from an old-growth Douglas-fir forest were measured in the laboratory and the field. The laboratory results indicate that typical epiphytic fruticose lichens, foliose lichens and bryophytes for old-growth Douglas-fir forests in the PNW could store 2.23, 3.42 and 9.99 times their dry weight in water, respectively. Although these values could be used to predict the maximum epiphyte-laden branch water storage under laboratory conditions, they were unable to do so under field conditions. In the field the biomass on the branch could not predict the maximum branch water storage because the branches: (1) were partially saturated for most of the measurement period; and (2) required greater than 30 mm of rain to saturate due to preferential flow routing water through the epiphyte mats. The frequent storms and the slow saturation of the canopy resulted an underestimation of S and an overestimation of E/R¯ by standard regression based techniques for estimating canopy variables. Lastly, the water stored on epiphyte-laden branches after exposure to natural rainfall was positively associated with rainfall intensity. The absorption of atmospheric water vapor by epiphytes in old-growth Douglas-fir forests in the PNW may have facilitated carbon uptake by green lichens and altered the energy budget of the forest during the seasonal summer drought. During the summer months the green lichens absorb sufficient quantities of atmospheric water to reactivate their photosystems. The diurnal absorption/evaporation of atmospheric water will result in significant uptake of water at night and may account for 5 to 21% of the canopy latent heat flux in the early morning (600 to 1000 h).
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650 4 $a Hydrology. $3 545716
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