Transcript Slide 1

Material cycles and flows
Decomposition
dL/dt = I – kL , where I = input and k =
decomposition rate
Decomposer food chains
Soil populations can be high
Microbial populations
bacteria
100,000,000 - 500,000,000 /g
actinomycetes
fungal myceta
1,000,000 /g
5,000,000 /g
Animal populations
nematodes
1,700,00-6,300,000 /m2
springtails & mites
earthworms
400,000 / m2 (conifer litter)
10,000 – 1,000,000 /acre
The Clemson experiment
Start with dead baby pig
Observe animal visitors
Day 1: Fresh
17sp
Day 2: Bloated
48 sp
Day 3: Active decay
255 sp
Day 4: Advanced decay
426 sp
Day 6: Dry
211 sp
Time course of N and P in pine litter
Initial
1 year
2 years
3 years
4 years
Fungal biomass
C/N
134
85
66
53
46
12
C/P
2630
1330
912
948
869
64
The critical value to
measure for organism
response is not total N,
or even available N, but
rate of supply of
available N. The same
applies to P
Terrestrial nitrogen cycle
Nitrogen fixation in nodules
Denitrifying Bacteria (anaero)
N2
Lightning, Photchemical
Nitrate Bact, 17 kcal/mole
NO3
Plants
Nitrogen fixers
Org N
Bacteria & bluegreen algae
(Nitrobacter)
NO2
65 kcal/mole
Nitrifying Bacteria
(Nitrosomonas)
Ammonifying bacteria
Plants
Terrestrial nitrogen cycle
NH4
Figure 8.6
Figure 8.7
Weirs are used to gauge stream flow; nutrient
loss is determined by flow times concentration.
Rain gauges and stemflow gauges are used to measure
influx in regular rain, rain falling through a canopy,
and rain running down tree stems.
Variation in atmospheric contributions of cations with distance
from the ocean.
Nutrient concentrations in rain water is increased by
flowing down stems or over leaves.
The standing crop of cations tends to show a net
loss compared to atmospheric input, whereas anions
and carbon tend to show a net gain.
Water loss to
evapotranspiration
tends to be
relatively constant
from year to year,
but total stream
flow is highly
sensitive to overall
rainfall.
Season pattern in stream water nitrate levels reflecting spring
melt with winter decomposition, and summer drawdown owing to
biomass increment.
Note year-to-year variance in stream water nitrate
levels at Hubbard Brook, but generally an upward trend
resulting from anthropogenic inputs.
Experimental manipulation of a watershed and comparison with
a control allowed the impact of disturbance on nutrient
dynamics to be assessed.
Cutting of a watershed at Hubbard Brook lead to a dramatic
increase in nitrogen release in stream water.
Loss of NO3 (mg/l) from control and
experimental watersheds.
Site
Disturbance
Cont
Dist
Hubbard Brook, NH
Kill plants 2 yrs
2.0
97.0
Gale River, NH
Commercial clearcut
2.0
38.0
Fernow, WV
Commercial clearcut
0.6
3.0
Coweeta, NC
Complex
0.05
7.3
Andrews, OR
Commercial clearcut
0.08
0.26
Summary Points – 1–
• Organisms depend on nutrients. Understanding of
ecosystem function must include understanding of nutrient
influxes, cycling, and losses.
• Decomposition is used to describe a large number of
interrelated processes by which organic matter is broken
down into particles and to soluble forms of nutrients that
are available for plant uptake
• The standing crop of litter can be modeled as input
divided by standing crop equals a system-specific
decomposition constant that varies with latitude, moisture,
temperature, and litter quality.
• Decomposer organisms are important for fragmenting,
mixing, and mineralizing dead organic matter
Summary Points – 2–
• The nitrogen cycle has many links that depend on
prokaryotic organisms, including nitrogen fixation,
ammonification, nitrification, nitrate production, and
denitrification.
• System-level studies of nutrient fluxes are often best
studied with closed systems such as ponds and watersheds.
• Most nutrient influx to watersheds comes from the
atmosphere and from weathering of rock and soil. Anions
tend to come from the former and cations from the later.
• Variation in nutrient loss is related to season, recent
disturbance events, and the degree to which the system is
increasing in biomass.