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Special Issue in “Hydrological Processes”
Hydrology and Biogeochemistry of Small Amazonian Catchments
Christopher Neill, Alex Krusche, Helmut Elsenbeer,
Jonannes Lehmann and Daniel Markewitz
Contact: cneill@mbl.edu
Submission: September 30, 2004
Carbon, Biogeochemistry, and Hydrology: Dynamics at the Terrestrial-Aquatic Interface
Johannes Lehmann, Mark Johnson, Eduardo Couto, Susan Riha, Luiz Carlos Mattos Rodrigues, Mara Abdo, Evandro Selva, and Erick Fernandes
Cornell UniversityUniversidade Federal do Mato Grosso
Surface origin of nutrient export with streams
Markewitz et al., 2001 Nature 410, 802-805OxisolForest, pasture, field cropsParagominas, Eastern Amazonia
Rapid leaching in microaggregated soil
a)
b)
Sa
ugsp
ann
ung
[h
Pa
]
0
100
200
300 0.1 m0.3 m0.6 m0.9 m1.5 m2.5 m
Uhrzeit [h] 3 5 7 9 11 13 15 17 19 21 23 1
Niede
rsch
la
g [m
m]
048
121620
Stra
hlung
s-
inte
nsitä
t [M
W/m
2]
02004006008001000
38.4mm
-0,1-0,3
-0,6
-0,9
-1,5
-2,5
Tiefe
[m
]
04.1 05.1 06.1 07.1 08.1
Nie
de
rsc
hla
g [m
m]
0
4
8
12
16
20
Strahlung
sinten
sität [M
W/m
2]
0
200
400
600
800
1000
Sa
ugsp
ann
ung
[h
Pa
]
0
20
40
60
800.1 m0.3m0.6 m0.9 m1.5 m2.5 m
Uhrzeit [h] 12 14 16 18 20 22 0 2 4 6 8 10 12
Niede
rsch
la
g [m
m]
048
121620
Stra
hlung
s-
inte
nsitä
t [M
W/m
2]
02004006008001000
48.0mm
c)
Rai
nfal
l [m
m]
Solar R
adiation[M
W m
-2]
010203040507090
110140200300
Suction [hPa]0.1 0.3
0.6
0.9
1.5
2.5
Depth [m
]
Jan 4 Jan 5 Jan 6 Jan 7 Jan 8
Renck, Lehmann 2004 Soil Science 169, 330-341
Xanthic HapludoxManaus
Examining the terrestrial-aquatic interface
0.85 Ha1.69 Ha0.78 Ha0.62 Ha
N0 50 100 Meters
1234 IKONOS Panchromatic Image
(Courtesy EOS-Webster)
Headwater watersheds
1
234
Juruena, Mato Grosso, Brazil
Decreasing solute concentrations with depth
Throughfall: 1.3 ±0.4 mg L-1 (N=109)
Leaching: 1.8 ±0.5 mg L-1 (N=25) (free draining lysimeters at 0.1m depth)
Groundwater: 0.6 ±0.2 mg L-1 (N=16) (piezometers)
Spring: 0.6 ±0.3 mg L-1 (N=61) (grab samples)
Stream: 0.7 ±0.3 mg L-1 (N=127) (grab samples, 50m from spring, similar at 2km)
Total N
organic N 5-20%
Forested Ultisol-OxisolSouthern Amazon, Juruena, MTN=4 watersheds ±SEJohnson et al. Sp. Session 4
Nitrate (kg ha-1 0.1m-1)
0 10 20 30 40
Dep
th (
m)
0.00.2
0.6
1.0
2.0
3.0
4.0
5.0
6.0
7.0
8.0
Nitrate (kg ha-1 0.1m-1)
0 10 20 30 40
Dep
th (
m)
0.00.2
0.6
1.0
2.0
3.0
4.0
5.0
6.0
7.0
8.0
Nitrate retention in acid subsoils
Forested Ultisol-OxisolSouthern Amazon, Juruena, MTN=4 watersheds ±SERodrigues et al. Poster 28.10-p
Nitrate (kg ha-1 0.1m-1)
0 10 20 30 40
Dep
th (
m)
0.00.2
0.6
1.0
2.0
3.0
4.0
5.0
6.0
7.0
8.0
More subsoil nitrate on plateau than close to stream
pH (CaCl2) 3.9-4.5
Spring: 0.7 ±0.7 mg L-1 (N=65) (grab samples)
Decreasing solute concentrations with depth
Throughfall: 6.9 ±2.3 mg L-1 (N=106)
Leaching: 8.4 ±2.7 mg L-1 (N=25) (free draining lysimeters at 0.1m depth)
Groundwater: 1.3 ±1.3 mg L-1 (N=42) (piezometers)
Stream: 2.1 ±1.8 mg L-1 (N=134) (grab samples, 50m from spring)
DOC
Forested Ultisol-OxisolSouthern Amazon, Juruena, MTN=4 watersheds ±SEJohnson et al. Sp. Session 4
Important soil control over hydrological flow paths
Elsenbeer, 2001, Hydrol Proc 15, 1751-1759
Spatial distribution of clay
Soil type control
DOC (mg L-1 ± s.e.)
>40%clay <20%clay(increasing with depth)
UltisolOxisol
2.2 ±0.5 (N=10)
17.4 ±2.0 (N=25)
1.3 ±0.5 (N=11)
11.5 ±2.3 (N=19)
Surface Runoff
Groundwater
Throughfall: 0.6 ±0.3mg L-1 (N=4)
Leaching: na
Groundwater: na (piezometers)
Spring: 4.1 ±1.2mg L-1 (N=28)(grab samples)
Stream: 2.3 ±0.6 mg L-1 (N=28) (grab samples, 50m from spring)
DIC
Decreasing solute concentrations with depth
Distance from spring (m)
0 20 40 60 80 100 120 140 1602500
CO
2 (
ppm
)
0
5000
10000
15000
20000
25000
30000
35000
y=24489.9/(1+0.1189X)r=0.79
Large losses of CO2 from emergent groundwater
Forested Ultisol-OxisolSouthern Amazon, Juruena, MTN=30(from 4 watersheds)
14
12
10
8
6
4
2 0
CO
2 -Caq (m
g L-1)
pH
4.5 5.0 5.5 6.0 6.5
CO
2 (
ppm
)
0
5000
10000
15000
20000
25000
30000
35000
y=-14098x+89779r2=0.91
Losses of CO2 and pH dynamics
Forested Ultisol-OxisolSouthern Amazon, Juruena, MTN=30(from 4 watersheds)
Distance from spring (m)
0 20 40 60 80 100 120 140 1602500
CO
2 (
ppm
)
0
5000
10000
15000
20000
25000
30000
35000
y=24489.9/(1+0.1189X)r=0.79
Losses of CO2 and Ca dynamics
Forested Ultisol-OxisolSouthern Amazon, Juruena, MTN=30(from 4 watersheds)
14
12
10
8
6
4
2 0
CO
2 -Caq (m
g L-1)C
a (
me
q L
-1)
140
120
100
80
60
40
20 0
CO2
Ca
Large losses of CO2 from emergent groundwater
DOC6.6%
DIC-Alk15.7%
CPOC0.3%
POC0.9%
CO2-C outgas evasion66.0%
CO2-C(aq)10.5%
Solid Phase1.2%
Forested OxisolSouthern Amazon, Juruena, MT(from 1 watershed)
C fluxes as percentage of total, rainy season 2004
Important CO2 evasion at the terrestrial-aquatic interface for
the Amazon Basin
Soil water drainage 1250 mm yr-1 (Richey et al., 2002)
17 mg CO2-C mm-1 (Juruena)
Basin-wide CO2 evasion of terrestrial C from streams:
128 Tg yr-1 at terrestrial-aquatic interface (estimated)
353 Tg yr-1 in large streams (Richey et al., 2002)
Terrestrial sources of CO2 evolution from large streams in the Amazon
Forested OxisolSouthern Amazon, Juruena, MT(from 1 watershed)
20%
33%
47%
Richey et al., 2002
Groundwater DOC
Groundwater CO2
Litterfall
36%
58%
7%
DOC
Groundwater CO2
POC
Sources of CO2 evasion at terrestrial-aquatic interface
DOC CO2
?
SOM CO2
?
Root respiration CO2
?
Sources of CO2
20-Jun 21-Jun 22-Jun 23-Jun 24-Jun 25-Jun 26-Jun
CO
2 (p
pm)
10000
15000
20000
25000
30000
35000
40000 0:00 8:00 16:00 0:00 8:00 16:00 0:00 8:00 16:00 0:00 8:00 16:00 0:00 8:00 16:00 0:00 8:00 16:00 0:00 8:00 16:00
Diurnal fluctuation of CO2 in groundwater seep
Forested UltisolSouthern Amazon, Juruena, MT
Conclusions terrestrial-aquatic interface
• Low leaching of DOC to groundwater and emergence in stream
• Significant in-stream generation of DOC and Ca• No in-stream generation of N• Significant subsoil source of dissolved CO2
• Large CO2 evasion at the terrestrial-aquatic interface with profound impact on stream biogeochemistry
• Root respiration is a likely important source in addition to DOC and SOM
Thank You
• LBA, Cnpq, NASA, UFMT• Rohden Inc., Apolinario Schuler• Cornell Einaudi Center, Department of
Crop and Soil Sciences, Cornell Biogeochemistry Program
• Alex Krusche, Jeff Richey• The entire field team in Juruena: Paulo
Nunes, Benedito, Elielton
Special Session 4
Soil Control on Stream Biogeochemistry
Thursday, 3:30-6:00 p.m.
Sala “Brasilia”
Special Issue in “Hydrological Processes”
Hydrology and Biogeochemistry of Small Amazonian Catchments
Christopher Neill, Alex Krusche, Helmut Elsenbeer, Jonannes Lehmann and Daniel Markewitz
Soil type control
Spatial distribution of clay
Juruena, MT
Month
Jan-04 Feb-04 Mar-04 Apr-04 May-04
Car
bon
loss
es f
rom
wat
ersh
ed (
kg)
0.01
0.1
1
10
100
1000
CO2
Dissolved OC
Particulate OC
Coarse POC
Large losses of CO2 from emergent groundwater
Forested OxisolSouthern Amazon, Juruena, MT(from 1 watershed)
In-stream generation of DOC and N (Ca etc?)
• Explanation of in-stream generation of DOC and N by C and N input via surface flow. Can we show some data on that? Could we show stormflow versus baseflow concentrations (at weir) of particulate C and say that during that period of course a lot of coarse OM stays in the stream (or do we have data for surface particulate surface flow into streams? I think we shouold have particulate flow on surface, but not into streams,- but maybe we should look at that as well as an alternative or additional option).
• Or maybe relationship between coarse C and DOC losses? (we would need to multiply the water amount by the DOC concentration to get at DOC amounts. Coarse C is already ok I guess from Evandro’s data.
In-stream generation of DOC and N (Ca etc?)
• Maybe DOC and N with distance (same period etc as CO2 from previous slide)? Out to the Juruena possible?
• The idea is to show that not much DOC and N is lost from groundwater, but from in-stream generation that ultimately came from surface flow
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