781
(40 32' N, 119 49' W) is at an altitude of about 1191 m. Vegetation at the site is about 90%
ereasewood; the remaining 10% consists of shadscale (At riplex confertifolia) and hopsage
(Grayia spinosa), growing in an area with shallow ground water. Greasewood shrubs have an
average crown height of about 0.5 m; the plant density was about 23% and the shrubs Leaf
Area Index was about 3 (on a scale of 0 to 4) in 1991. Railroad Valley is located in east-
central Nevada. The field study site (38 30' N,115 46’ W) is at an altitude of about 1454 m.
Vegetation at the site is greasewood with minor amounts of shadescale. The shrubs had an
average crown height of about 0.5 m; the plant density was estimated to be about 20% and
the greasewood LAI was estimated to be about 2.5 to 3 in 1992.
Data collected at each site include incident and reflected short-wave radiation,
incident and emitted long-wave radiation, air temperature and vapor pressure at two heights,
wind speed at two heights, soil heat flux and soil temperature, soil surface temperature, and
canopy temperature. These data were used to solve the energy budget equation using the
Bowen ratio method. Net radiation was determined by summing the four measured
components of the radiation budget. These components were measured with Eppley spectral
pyranometers (PSP) and infrared radiometers (PIR). The PIR’s were equipped with
thermistors to measure dome and case temperatures so that the measured long-wave
radiation could be corrected for temperature gradients between the dome and case.
Corrections in net long-wave radiation typically are on the order of about -8 to -12 W/m-
dunng midday hours and about -4 to +6 W/m- at night. Vapor pressure gradients were
determined by measuring dew-point temperature at two heights using Campbell Scientific,
Inc. single-cooled-mirror hygrometer. The measuring heights were 1.25 m and 2.25 meters
above the soil surface. Air is alternately drawn through intakes at each height and routed to
the cooled mirror; a single pump aspirates the system. Numerous problems associated with
systematic sensor error are avoided by this system. However, operating limitations of the
cooled mirror under conditions of high temperature and low humidity can lead to invalid
vapor pressure data. These conditions occur when ambient temperature approaches 35 C and
humidity drops below 10 %. This is a common occurrence in central Nevada in July and
August. Air temperature was measured at the same two, heights, using 76 pm diameter
unshielded, non aspirated chromel-constant thermocouples. Soil flux was measured with two
Radiation Energy Balance Systems heat flow transducers buried at a depth of 0.05 m.
Changes in heat storage in the soil layer above each transducer was measured by four
thermocouples wired in parallel so as to provide a spatial average soil temperature. Two
thermocouples were place above each transducer, one at a depth of 0.01 m and the other at
0.03 m. The change in soil temperature measured by the thermocouples together with
periodically measured soil-water content and soil bulk density and an estimated value for the
specific heat of dry soil were used to calculate changes in soil heat storage in the interval
above the flux transducers. This heat storage was added to the flux value measured by the
transducer. Vapor pressure and air temperature were sampled at 1 second intervals and
averaged over 1 hour periods. Radiation, soil heat flux, and soil temperature were sampled at
10 seconds intervals and averaged over 20 minutes periods. In addition to these
measurements soil surface temperature was measured using an Everest interscience 1R
sensor, model 4000 with a 15 degrees filed of view, mounted 2 m above the soil surface. At
this height the sensor views an area of bare soil about 0.45 m in diameter; areas of bare soil
at the study site typically are as much as 3 m by 3 m. Canopy temperature was measured with
an Everest Interscience IR sensor model 110 or model 4000 with a 3 degree field of view,
also mounted about 30 cm above the top of the canopy. Wind speed was measured at 1.25
and 2.25 m above the soil surface using photo-chopper anemometers with a threshold of 0.2
