Th. Webb et al., Quantifying variability of soil physical properties within soil series to address modern land-use issues on the Canterbury Plains, New Zealand, AUST J SOIL, 38(6), 2000, pp. 1115-1129
Lack of accurate data to estimate soil physical properties for soil types i
s limiting the wide application of simulation models to address modern envi
ronmental and land-use issues. In this study, systematic sampling of soil p
rofiles for soil physical characteristics has provided an improved basis up
on which to estimate a number of soil physical properties for 4 soil series
. The selected soils form a soil drainage sequence on the post-glacial surf
ace of the Canterbury Plains and vary from shallow sandy loam, well-drained
soils to deep clay loam, poorly drained soils. Three profiles within 3 map
units were sampled for each of 4 soil series. Three horizons in each soil
profile were sampled for soil porosity values, particle size, and saturated
and near-saturated hydraulic conductivity.
Variability in all data, as shown by coefficient of variation, increased in
the order: total porosity = field capacity < wilting point < total availab
le water = clay content < readily available water < macroporosity < sand co
ntent < hydraulic conductivity. Hydraulic conductivity exhibited high varia
bility within horizons, between profiles, and within soil series. Temuka su
bsoils had extremely high variability in saturated hydraulic conductivity a
nd this could be explained by their coarse prismatic structure.
Analysis of variance identified horizons that differed in soil physical pro
perties between soil series. Horizons that do not differ between series may
be given pooled soil property values for the pooled series. Total porosity
, field capacity, wilting point, clay content, and near-saturated hydraulic
conductivity had the greatest number of differences (60-70%) between serie
s comparisons, while total available water had fewest differences (5%). The
series with greatest differences in drainage class (Temuka compared with E
yre or Templeton soils) recorded the largest number of differences in water
release characteristics and particle size. There were few differences betw
een well-drained Eyre and moderately well-drained Templeton series. Subsoil
s of Eyre series differed in hydraulic conductivity from subsoils for the o
ther 3 series, but few differences in hydraulic conductivity were found bet
ween horizons of Templeton, Wakanui, and Temuka series. Hydraulic conductiv
ity estimates for these series can therefore be pooled.