Southern Regional Fact Sheet
September,
2004 SERA-IEG-6*3
A New Method for Measuring
Lime Buffer Capacity
Introduction:
Most buffers contain some toxic chemicals; therefore, many
labs are looking for alternatives to determine the lime requirement of soils.
Through research at the
Soil pH and lime recommendations:
Soil pH is an important chemical property because it
influences the availability of soil nutrients for plant uptake and it affects a
crop’s root system development. Soil pH also indicates whether lime is needed
for correcting toxicities caused by aluminum and manganese, or for increasing
calcium levels in the soil. But pH alone does not indicate how much lime is
needed because soils vary in their soil pH buffering capacities, i.e., a soils
resistance to a change in pH (the amount of soil acidity that must be
neutralized to raise pH to any given level). Most
soil testing laboratories make lime recommendations from a calibration based on
soil pH and a buffer pH measurement, but they do not directly measure the
acidity that must be neutralized by lime application.
What is the LBC?
The LBC is a fundamental property of the soil. It is a measure of the amount of soil acidity that must be neutralized to raise soil pH by one unit, expressed as pure calcium carbonate. For example, it is the parts per million of pure and finely ground calcium carbonate (pounds of pure calcium carbonate per million pounds of soil) needed to raise soil pH from 5 to 6. Based on the weight of soil in an 8-inch plow depth and on the reactivity/purity of available liming materials, a multiplier of 4 converts LBC values into lbs of ag lime per acre to raise pH one unit. In the figure below, the soil with LBC of 250 would require 1000 lbs of ag lime to raise pH of that soil from 5 to 6.
Lime Recommendations:
The primary purpose of the LBC Method is to calculate a lime recommendation. A lime recommendation is calculated based on three factors: 1) the soil’s initial pH in a dilute solution of calcium chloride, 2) the desired pH for the field or soil area being analyzed, and 3) the soil’s LBC, which is calculated from the change in pH from adding the fast acting lime to the soil. Lime recommendations are typically for an 8-inch depth of soil. In this case, the lime recommendation is:
Lbs ag
lime = LBC X (target pH – pHCaCl2) X 4
How much does LBC vary between soils?
The LBC varies primarily because of differences in the soil
organic matter and clay contents of soils. We have found the LBC to vary as
much as tenfold within crop production fields in
Figure 1. Lime Buffer Capacity of two
Why the LBC is a useful measurement?
As mentioned above, the primary purpose of the LBC method is to calculate a lime recommendation, but it can also be useful for other purposes. Since the LBC Method directly measures soil acidity, it can be used in a calculation, along with soil test calcium, magnesium, and potassium values to provide a reasonable estimate of soil cation exchange capacity. The measurement of LBC will not change appreciably over time because soil levels of clay and organic matter remain about the same from year to year in typical agronomic farming operations. Therefore, the LBC does not need to be measured annually to calculate a cation exchange capacity for a field or field area. For soils amended with heavy applications of organic materials (gardens, potting soils, flower beds, etc.), annual measurements would be needed to calculate the cation exchange capacity.
D.E. Kissel and P.F. Vendrell,