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Four centuries of soil carbon and nitrogen change after severe fire in a Western Cascades forest landscape

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Title Four centuries of soil carbon and nitrogen change after severe fire in a Western Cascades forest landscape
Names Giesen, Thomas William (creator)
Perakis, Steven S. (advisor)
Date Issued 2006-01-03T22:36:40Z (iso8601)
Internet Media Type application/pdf
Note Graduation date: 2006
Abstract Fire is a major disturbance process in many forests. Long-term studies of the
biogeochemical effects of fires, especially on soils, are very rare.
Consequently, long-term effects of fire on soils are often hypothesized from
short-term effects. In a chronosequence study, I studied 24 western Cascades
(Oregon) forest stands thought to have been initiated in fire. Twelve of those
burned about 150 years ago (“young” sites), and the other 12 burned an
average of 550 years ago (“old” sites). I hypothesized that young stands would
have less carbon (C) and nitrogen (N) in forest floor and in 0 -10 cm mineral
soil than old stands. I found that forest floor N pools of old sites (average =
1,823 kg/ha ± s.e. = 132 kg/ha) were significantly greater than young sites
(1,450 ± 98 kg/ha). Similarly, forest floor C pools of old sites (62,980 ± 5,403
kg/ha) were significantly greater than young sites (49,032 ± 2,965 kg/ha).
Greater N and C pools in forest floor of old sites resulted from greater forest
floor mass in old sites; concentrations of both N and C, and C:N ratios, did not
differ significantly by forest age class. In mineral soil, neither concentrations
nor pools of N and C differed between young and old sites. Despite overall
similarity of C:N ratios in young versus old sites, potential N mineralization
rates were twice as high in forest floor of old sites (average = 60 ± 7.3 mg N /
g soil) than young sites (26 ± 3.5 mg N / g soil), . Nitrate accounted for only
2% or less of total N mineralized in forest floor samples. In mineral soil,
potential net N mineralization did not differ by forest age class. The pattern of
high net N mineralization and low nitrification in old forests is consistent with
other studies of fire-prone forests, yet contrasts with many studies of forests
that lack fire, and suggests that ammonium is not the sole control over
nitrification in fire-prone ecosystems. Overall, fire appears to impart a longterm
legacy of reduced forest floor N and C pools in this western Oregon
Cascades landscape, which suggests that current fire-suppression activities in
the region may increase forest floor N and C storage over historical conditions
within several centuries. The differences in forest floor and soil N cycling
processes that I observed by forest age class raise the further possibility that
fire exclusion in these forests may change the relative abundance of soil
inorganic N forms to favor ammonium over nitrate. Such changes may have
unknown consequences for relative competitive abilities of plant and microbial
species that rely preferentially on different N-forms to meet N nutrition
requirements.
While forest floor N and C pools increase from young to old stands, forest floor
and soil N and C pools are not different, or decline, between 450 year old
stands and the oldest stands at 800+ years, That, and other, anomalous
changes in values from ~450 to 800+ years, suggest possible changes in
ecosystem functions, and may indicate that this landscape could be a fruitful
study area for examinations of a mature, steady-state ecosystem
Genre Thesis
Topic carbon
Identifier http://hdl.handle.net/1957/785

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