Winter wheat is commonly grown in dryland cropping systems in the Pacific
Northwest region of semi-arid eastern Oregon. For agronomic, economic, and
environmental reasons, it is important to understand the long-term sustainability of such
dryland systems.
The objective of this study was to evaluate the long-term effects of tillage,
nitrogen (N), soil depth, and the influence of precipitation on wheat yields in dry land
cropping systems of eastern Oregon. Data were taken from the Tillage/Fertility or
"Balenger" experiment, which was established in 1940 by a Soil Conservation employee,
and is one of the oldest replicated research experiments in the western United States. The
experiment consisted of a winter wheat-summer fallow rotation arranged in a randomized
block design with three replications. The main plot consisted of three primary tillage
treatments (moldboard plow, offset disk, and subsurface sweep) and subplots consisted of
six nitrogen treatments that changed over time and most recently ranged from 0 to 180 kg
ha�����. Soil depth of individual plots ranged from 1.2- to 3.0-m. The study was divided
into four main time periods (1940-1951, 1952-1961, 1962-1987, and 1988-1997) within
which experimental treatments were consistently maintained.
The moldboard plow tillage treatment significantly increased yields by more than
300 kg ha����� over the subsurface sweep tillage treatment in all four time periods. Yields
with the moldboard plow system were significantly higher than with the offset disk
system in time periods 3 and 4. The same trend was evident for mean yield in time
periods 1 and 2, but differences were not statistically significant. In time periods 1, 2,
and 3, mean yields were higher with the offset disk tillage treatment than the subsurface
sweep tillage system, although the differences were not statistically significant. In time
period 4, mean yield was higher for the subsurface sweep system than the offset disk
treatment, but differences were not statistically significantly.
The optimum amount of N for winter wheat differed from year to year, within,
and between experiment periods. This was apparently in response to rainfall patterns and
improved management factors, specifically more N responsive semi-dwarf varieties. For
time period 1, the maximum fertilizer rate was 11.2 kg N ha�����, which tended to produce
higher mean grain yields than an application rate of than 0 kg N ha�����, regardless of the
quantity or distribution of precipitation. For time period 2, the maximum fertilizer rate
was 33.7 kg N ha�����, which produced significantly higher grain yields than an application
rate of than 0 kg N ha�����, regardless of the quantity or distribution of precipitation. For
time period 3 (1962-1987), which had below-normal annual and growing season
precipitation, yield increased with the addition of 45 kg N ha�����. For time period 4 (1988-
1997), which had above-normal annual and growing season precipitation, yield increased
with the addition of 90 kg N ha�����. Yield increases at greater rates of N were insignificant.
For time periods 3 and 4, maximum mean yield was obtained at an application rate of 135
kg N ha�����. The response of wheat yield to N during dry years was greater for deep
(> 2.8 m) soils than for shallow soils. In addition to amount, rainfall distribution during
the winter (October to March) and growing (April to June) season significantly affected
yield.
Results demonstrate the importance of rainfall and nitrogen to winter wheat
production in eastern Oregon, and that the most environmentally sound tillage systems
are not necessarily the most profitable from farmers' point of view. / Graduation date: 2000
| Identifer | oai:union.ndltd.org:ORGSU/oai:ir.library.oregonstate.edu:1957/33175 |
| Date | 07 December 1999 |
| Creators | Camara, Kelli Marie |
| Contributors | Payne, William A. |
| Source Sets | Oregon State University |
| Language | en_US |
| Detected Language | English |
| Type | Thesis/Dissertation |
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