WORKING GROUP 4
OLSON
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each of six trees in each of the four broadleaved species. For the coniferous
species, between one and two ounces of needles were picked from the same
relative crown position. Foliage samples were picked between 10.00 and
14.00 hours local sun time, but no samples were picked when foliage sur
faces were wet. All samples were taken to the laboratory where reflectance
measurements were completed within one hour of the time of picking. A
General Electric recording spectrophotometer having a slit width of 10 milli
microns and a wavelength range from 400 to 700 millimicrons was used. In
cident energy was normal to the foliage surface, and the specular component
was largely included in the measurements.
In addition to the foliage sampling program, additional measurements were
taken in each broadleaved plantation. A dial-gauge micro-dendrometer was
used at weekly intervals to measure accumulated radial growth at breast
height to the nearest 0.001 inch. Soil moisture was determined gravimetrically
in each plantation at weekly intervals and was used to determine total avail
able soil moisture in the upper 30 inches of the soil. Chemical analyses of the
chlorophyll content of tree foliage were made at bi-weekly intervals for each
broadleaved species.
Partial weather data were collected for the study area. A continuous
recording Bendix hygrothermograph and an Instruments, Inc. continuous
recording pyrroheliometer were maintained in an open area which was
within 300 yards of each of the six plantations. U.S. Weather Bureau standard
and recording rain gauges were also installed at this location.
Results
Differences in foliage reflectance between the two pine species studied were
insignificant at any one sampling period. Until early June, both pine species
reflected less light at all wavelengths sampled than did the four broadleaved
species. By mid-June, increased reflectance from pine due to the growth of new
pine foliage, and decreasing reflectance from broadleaved foliage, essentially
eliminated any difference in total reflectance between foliage types for the
400- to 700-millimicron region. From mid-June to late October, reflectance
from pine foliage remained nearly constant.
Changes in light reflectance during the growing season were much greater
with each broadleaved species than with pine. Average reflectance curves for
four different dates during the growing season are shown in Fig. 1. Except in
sycamore, reflectance at 680 millimicrons increases steadily during the growing
season.
The decreasing reflectance at 680 millimicrons noted in sycamore is believed
to be associated with a disease commonly called Anthracnose, caused by the
fungus, Gnomonia veneta (Sacc. & Speg.) Kleb. The growth records (fig. 2)
for the four plantations suggest that the disease attack was severe. The relatively
low growth rate of the silver maple may have been due to an attack by the
same, or a similar, fungus. However, the silver maple was located on poorer
