Hydrogeological assessment of two important wetlands (GDEs) in Hodgson's Wetland suite

SCHOOL OF EARTH AND ENVIRONMENT

Nathan Senevirathne

Supervisor

Associate Professor Ryan Vogwill

Oct

2013

Regional setting of project area

BMNDRC

Study area

The study area is part of Buntine-Marchagee Natural Diversity Recovery Catchment (BMNDRC)
The University of Western Australia

Regional setting of project area
Study area sub-catchment
(~ 600 ha = 0.02 % of BMNDRC)

W023
W024

W023

W024


Remnant vegetation and landuse
~90%

Wheat Plantation

Lupin Plantation

~4%

Canola Plantation

Re-vegetated in 2013

Salt – tolerant shrubs

Eucalyptus overstory

Geology & Topography
•
•
•
•
•

Drilling program carried out in mid 2012
LiDAR data
Geological survey of Western Australia by Baxter & Lipple 1985
The geology, physiography and soils of wheatbelt valleys by Commander et al. 2001
Regolith geology of the Yilgarn Craton, Western Australia: implications for exploration by Anand & Paine 2002

 The entire study area is a low relief region that lies over Archaean
granitic rock of the Yilgarn Craton; ~340 mAHD on WEST and ~290 mAHD
on EAST
 The typical soil structure is comprised of fresh granitic bedrock grading
upwards into saprock and saprolite which are overlain by lacustrine
clays, palaeochannel silts, yellow earthy sands (Balgerbine Soil System)
(Anand & Paine 2002)

 Basement rocks are exposed only at a small area near western margin
and maximum depth is about 35 m
 There is only one dyke appearing just outside of south-west margin
(Geological Survey Western Australia by Baxter & Lipple 1985)


Soil types, dykes and isolated outcrops of granite in the study area
(Baxter & Lipple 1985)


The gradient of slope in the study area


A

B

C

B

A
C

D
D

Digital elevation profiles of study
area using LiDAR elevation data

Groundwater monitoring network


Methodology Surface water catchment delineation
surface flow that could be generated by
a heavy rainfall

W023

W024


Methodology Surface water catchment delineation

New Boundary

618 ha
589 ha


Methodology Hydrogeochemistry
 Water samples were collected from monitoring bores and several wetlands on 30th
April 2013. Electrical Conductivity (EC), Oxidation-Reduction Potential (ORP), pH,
and temperature were measured at the field.

 Ion chromatography using Dionex DX500 systems to determine the concentrations
of major cations and anions

Na-Cl type

Na-Cl type

waters

waters



Dominance of Cl-, Na+, SO42-, Mg2+ and HCO3- in water samples
Molar Cl/Br ratios vs. Cl- concentrations (mol/L) in water
samples collected from groundwater and wetlands


Distribution of Total Dissolved Solids (TDS) in study area


Methodology Conceptual model of wetland-scaled water balance
Open water body ET
Rainfall
Surface water in-flow
Superficial in-flow

Bare soil ET
Surface water out-flow
Superficial out-flow

Saprolitic
Aquifer
Saprolitic

Saprolitic

discharge

recharge

Bedrock


Methodology Conceptualising groundwater flow

B

A’

B’
A

Transects of hydrogeological profiles marked on study area sub-catchment



Groundwater equipotential lines and flow in shallow aquifer


Groundwater equipotential lines and flow in the saprolitic aquifer

Methodology Evapotranspiration
Open water body Evapotranspiration

0.7
(Marimuthua, Reynoldsa & Salle 2005; Allison 1974;
Tweeda, Leblanca & Cartwright 2009)
(Tweeda, Leblanca & Cartwright 2009)

Where


Methodology Evapotranspiration
Estimating bare soil evapotranspiration - Chen (1992)
Monthly bare soil ET with E1 (0.024 of Epan) and E2 (0.4 of Epan)
Epan

Jan
Feb
Mar
Apr
May
396.4 357.7 310.5 191.4 121.1

Jun
72.8

Jul
81.4

Aug
97.2

Sep
Oct
Nov
Dec
131.2 209.0 281.2 379.4

Mean number
of days of rain
≥1mm

2.0

1.8

2.2

1.5

5.0

6.2

7.5

6.4

5.1

2.6

2.0

1.7

E1 (mm/month)
E2 (mm/month)

8.3
20.5

7.5
18.4

6.4
17.6

4.1
7.7

2.0
15.6

1.0
12.0

1.0
15.7

1.4
16.1

2.1
17.8

4.2
14.0

5.8
15.0

8.1
16.6

mid Feb – beginning June
(4 months)


Methodology Surface water run-off

(Groen and Savenije 2006)

•

Assumed that surface run-off within the immediate vicinity of W023 and W024
Jan

Surface run-off from
area of 1000 m 2

Mar

Apr

May

Jun

Jul

Aug

Sep

Oct

Nov

Dec

Annual

6.8

5.1

7.3

4.4

15.4

17.1

22.1

18.4

14.2

7.4

5.3

5.5

129.1

Jan

Monthly Interception
(Im) - mm

Feb

Feb

Mar

Apr

May

Jun

Jul

Aug

Sep

Oct

Nov

Dec

Annual

4.5

1.2

4.0

1.3

5.3

3.5

6.0

4.5

3.0

1.7

0.9

2.6

38.6

(m3 )



Possible flow patterns of surface water in-flow (generated using ArcGIS 10.1)

Elevation profiles across W023 and W024
A

A

B

D

H
W023

D

C

C

F

E

W024
G
G

B
H

E

F


Estimation of surface area of water body

W etland

Highes t
s urafce Area
(m 2 )

Highes t water
lev el (m)

Annual minimum
water lev el (m)

Surface area at
minimum depth
(m 2 )

Av erage s urface
area (m 2 )

W 023
W 024

7623.5
10584.0

1.35
0.64

0.70
0.00

1475.9
0.0

4549.7
5292.0


Results

Water and Chloride balance of W023

Volume
(m 3 /y ear)

Cl concentration
(mg/L)

Cl - Mas s
(kg/y ear)

2188.7
1980.0

8.0
1036.0

17.5
2051.3

Section 3.1 and 3.12

Vertical groundwater inflow (GW in )

1048.9

1036.0

1086.7


Surface water inflow (SW in )

4061.1

8.0

32.5

INPUT
Precipitation (P)
Horiz ontal groundwater inflow (GW in )

9278.7
OUTPUT
Horiz ontal groundwater outflow (GW out )
Open water body ev apotrans piration (ET)

Comments


3188.0
1825.0

9370.2

Total input

2628.0

Section 3.10.1 and 3.12

2628.0

1440.0
7930.2

Percentage
of error

Total output

3

-91.5

m /y ear

-12.0

mm/y ear

560.0 kg/y ear Balance

Water and Chloride balance of W023 for a period of 12 months (from Sep 2012 to Sep 2013)


Results

Water and Chloride balance of W024

Volume
(m 3 /y ear)
INPUT
Precipitation (P)

Cl concentration
(mg/L)

Cl - Mas s
(kg/y ear)

3116.2
1055.9

8.0
1097.0

24.9
1158.3

2923.4

8.0

23.4

7095.5
OUTPUT
Bare s oil ev aporation (ET)


1206.7
1921.0

Total input

1517.1

Section 3.10.1 and 3.12

1517.1

789.8
5062.9
981.2
6833.8
261.7
34.3

Comments

Total output

3

m /y ear
mm/y ear

-310.5 kg/y ear Balance

Water and Chloride balance of W024 for a period of 12 months (from Sep 2012 to Sep 2013)


Results

Discussion

Water quality
W 023
3.8 to 7.43

W 024
0.18 to 7.92

pH

7.49 to 9.08

6.95 to 8.65

Redox potential (eh mV)

EC (mS/cm)

- 97.5 to 205

- 65 to 201

Cl- (mg/L)

1825

1921

TDS (mg/L)

3448

4826

Water balance components of W023
Volume
(m 3 /y ear)

24%
21%

INPUT
Precipitation (P)

Cl concentration
(mg/L)

Cl - Mas s
(kg/y ear)

2188.7
1980.0

8.0
1036.0

17.5
2051.3

1%
64%

11%

Vertical groundwater inflow (GW in )

1048.9

1036.0

1086.7

34%

44%


4061.1

8.0

32.5

1%

9278.7
15%
85%

OUTPUT

3188.0

1440.0
7930.2

1825.0

9370.2

2628.0
2628.0

3

-91.5

m /y ear

-12.0

mm/y ear

560.0 kg/y ear


Results

Discussion

Water balance components of W0234
Volume
(m 3 /y ear)
44%
15%
41%

INPUT
Precipitation (P)

Cl concentration
(mg/L)

Cl - Mas s
(kg/y ear)

3116.2
1055.9

8.0
1097.0

24.9
1158.3

2%
96%

2923.4

8.0

23.4

2%

7095.5
12%
74%
14%

OUTPUT
Bare s oil ev aporation (ET)

789.8
5062.9
981.2
6833.8
261.7
34.3

Uncertainty

1206.7
1921.0

1517.1

100%

1517.1
3

m /y ear
mm/y ear

-310.5 kg/y ear

Component

Error %

Reference

Lake-to-Pan coeff

30%

(Tweeda, Leblanca & Cartwright 2009)

Surface area (Surface water, ET)

Winter (1981), TBRG - (Australian Bureau of Meteorology 2011)

Precipitation

16% - 26%

Winter (1981), TBRG - (Australian Bureau of Meteorology 2011)

Groundwater (Hydraulic conductivity)

40%

slug tests in Nabappie subcatchment – Variability in Average

Groundwater (Capture zone – ± 0.5)

10%

Statistically

Cl- content in surface water

Nabappie catchment 500 to 5000 mg/L Bourke (2011)


Results

Conclusion

W023 & W024
•
•
•
•
•

Flow-through wetlands
Direct contact with the water table of the surficial aquifer
Can be assumed that both of the wetlands are underlain by a silcrete hardpan
Hydrogeochemically different
Majority of inputs being sourced from groundwater and surface water runoff
components.
• Considerable attention should be given to the surface water runoff component
because it may carry a significant amount of solutes to wetland W023 (Winter
1981).


Results

Conclusion

W023
concept is supported by the occurrence of
mature perennial vegetation in the northern
half of wetland W023


Results

Conclusion

W024
concept is supported by the occurrence of
mature perennial vegetation in the northwestern part of wetland W024


Results

Conclusion

Iso- annual average total dissolved solids (TDS mg/L) curves along AA’


Questions


Hydrogeological assessment of two important wetlands (GDEs) in Hodgson's Wetland suite

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