112.3
-To show that intense management can increase the rate at which soil quality improves
-To compare soil quality between two different management intensities (greenhouse beds and fallow fields) by testing the following soil properties:
-% Soil Organic Matter (SOM)-pH-Cation Exchange Capacity (CEC)-% base cation saturation ([Ca2+],
[Mg2+])
Comparison of soil properties in raised bed greenhouse and adjacent fallow fields: effects of 3 years of intense
organic management at the Jones Farm Ona Lindauer, Shannon Morris, Rob StengerResearch Project for Systems Ecology (ENVS 316) Fall ‘04
Oberlin College, Oberlin, OH
Main Objective -Our two study areas were 1) intensively managed
greenhouse beds (planted in April 2002 after leaf mulch and chicken manure fertilization)
2) unmanaged fallow fields (uncultivated since 2000)
Methods
Results & Discussion
1)Three years of intense management will give the greenhouse beds a higher SOM.
2)Higher SOM in greenhouse beds will lead to a higher CEC
3)Higher pH in greenhouse beds will lead to a higher % base cation saturation
-Greater SOM content and higher pH mean more cation exchange sites for base cations to occupy.
-Higher SOM found in intensively managed organic agricultural soils may have a higher CEC than soils which do not receive high inputs of organic material.
-A higher pH may lead to a higher CEC.
-The rate of soil quality improvement observed as a result of intensive soil management at the Jones Farm can be used to guide agricultural practices elsewhere.
-The Jones Farm is an organic farm managed as part of the Oberlin Sustainable Agriculture Project since 2000, prior to which the farm was under conventional roundup-ready soybeans cultivation.
-Soil quality has not been fully assessed since 2000.
-Current assessment could inform future management decisions in soil development.
N
F4
F3
F2 F1
GA
GB
The Jones Farm located in Northeast Ohio with sample areas. GA and GB are the greenhouses. F1-4 are the fallow field sample sites.
Comparison of average soil properties from averaged sub-plot data at Jones Farm, with standard error bars and base cation concentrations adjusted for scale. Differences in pH, % SOM, CEC, [Mg2+], and [Ca2+] between our two sample sites were all highly significant.
Conclusion
Hypotheses
Background-We used standard techniques (Petersen 2004) to extract soil cations and assess CEC with sequential additions of NH4Cl and KCl.
-CEC was measured from the ammonium extract using an ammonium probe, base cation concentrations were assessed using a Dionex Ion Chromatograph
-% SOM was measured via combustion and pH was taken with a pH probe.
Regression between SOM and CEC in soil samples from individual sub-sample plots at Jones Farm. R2 value shows the strength of the relationship.
Regression between pH and CEC in soil samples from individual sub-sample plots at Jones Farm. R2 value shows the strength of the relationship.
R2 = 0.9603
0
5
10
15
5 10 15 20SOM (%)
CE
C (
cmo
l (+
)/kg
)
R2 = 0.7249
0
5
10
15
5.0 5.5 6.0 6.5 7.0 7.5pH
CE
C (
cmo
l (+
)/kg
)
Field Greenhouse
R2 = 0.9603
R2 = 0.7249
Works CitedPetersen, J.E. 2004. Methods for analyzing aquatic ecosystems, unpublished.
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