south-west western australia sustainable yields …...csiro swwasy project – water...

South-West Western Australia Sustainable Yields Project

Don McFarlaneProject Leader

CSIRO SWWASY Project – Water Corporation

Broad terms of reference

• Estimate the current and 2030 yield of water in catchments and aquifers for the south-west of WA considering climate change and development (plantations, farm dams, groundwater abstraction)

• Compare the estimated current and future water yields to those needed to meet the current levels of extractive use, future demands and environmental needs


Publications

Main reports Executive summaries

FactsheetsWeb: www.csiro.au/partnerships/SWSY.html

Presenter

Presentation Notes

The results are contained in three main reports of 170 to 330 pages in length – one on surface water; one on groundwater and one on water yields and demands. There are also three executive summary reports of 12 to 16 pages in length. The third one of these contains results from all there areas Finally there are four 4-page Factsheets with the Key Findings summarised for each area of work.


Location of the project area

• All fresh, marginal and brackish surface water catchments between Gingin Brook and the Hay River

• All aquifers within the Perth and Collie basins, plus the western Bremer Basin

• Area = 62,500 km2

Presenter

Presentation Notes

The project area includes all of the fresh, marginal and brackish water resources in SWWA The surface water basins are shown in blue and extend from Gingin Brook to the Denmark and Hay catchments. The saline Avon, Murray, Blackwood and Frankland Rivers were not modelled The groundwater resources are shown in red and include the Perth Basin west of the Darling Fault, the Collie Basin and the western part of the Bremer Basin near Albany.

CSIRO SWWASY Project – Water CorporationCSIRO South-West Western Australia Sustainable Yields Project – Overview

Project area topography

• Short streams that arise in the Darling Ranges are fresh

• Darling Fault separates Perth Basin from Darling Plateau

• Coastal plains are flat and low lying – Swan Coastal Plain; Scott Costal Plain; South Coast

• Perth Basin Plateaux are higher in elevation

Presenter

Presentation Notes

The yellow line shows the project boundary. The blue (cooler) colours are areas with a low elevation and the hotter colours are high. Only short streams that arise in the Darling Ranges are fresh and were modelled. Not all of the Perth Basin has a low elevation. The Swan Coastal Plain is very low and flat as a result of ocean inundation in the Pleistocene but the northern plateaux, and to a lesser extent the Blackwood Plateau, are moderately elevated.


Scenarios

• The ‘historical climate’ or Scenario A assumed that the climate of the last 33 years (1975 to 2007) would continue. This was used as a base case for comparison of other climate scenarios

• The ‘recent climate’ or Scenario B assumed that the climate of the last 11 years (1997 to 2007) would continue

• The ‘future climate’ or Scenario C used 15 GCMs with 3 GHG emission levels which would result in 0.7, 1.0 and 1.3oC of warming by 2030 = 45 possible climates. They are reported as

• wet future climate (Cwet)• median future climate (Cmid) and • dry future climate (Cdry)

• Current levels of abstraction and land use were assumed to continue for all scenarios above

• The ‘future climate and development’ or Scenario D assumed a median future climate and full groundwater abstraction. New plantations and farm dams where not estimated to be important


South-west WA has had reduced rainfall since 1975

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Presenter

Presentation Notes

It is generally accepted that the south west of WA experienced a climate shift in about 1975 when rainfall decreased. The average decrease for May to July rainfall was about 18% with a lesser decrease between August and October. All future projections of changes in rainfall, runoff and groundwater replenishment use the post 1975 period as a baseline. i.e. we are ‘factoring in’ this decrease and comparing all future estimates with this already dry period. This is unlike all other Sustainable Yield projects where a similar climate shift is not apparent in their record. They used long term climate records that include wetter periods in the past.


Annual rainfalls have been even drier since 1997

1997 to 2007 rainfall compared with

1975 to 1996 rainfall

Presenter

Presentation Notes

Comparing the rainfall of the last 11 years, the Recent Climate, with the previous 22 years between 1975 and 1996 shows that the south coast has been less affected than the central and northern parts of the project area. The left hand map shows the difference in percent and the right hand in mm per year. Some areas in the Peel – Harvey area have had annual rainfalls more than 100 mm less than in earlier years.


14 of 15 GCMs project it will get drier

Mid warming

Low warmingHigh warming

• Median future climate -7%

• Wet extreme future -1% climate (90 percentile)

• Dry extreme future -14% climate (10 percentile)

Change in annual rainfall

Presenter

Presentation Notes

This graph shows what 15 global climate models project for 2030 rainfall in the project area. The models are ranked on the vertical axis and the estimated change in annual rainfall is shown on the lower axis. Three global warming scenario are also shown – high warming or 1.3o C which would be expected if GHG emissions are high, mid warming or 1.0o C which equates to median emissions and low warming or 0.7o C which assumes that GHG emissions will be lower. Almost all models projects a drier climate with the median being a reduction of about 7% compared with the Historical Climate and with a range of 1 to 14 percent reduction. It must be remembered that the baseline already includes a reduction in rainfall and this projection is in addition to that which has been recorded since 1975. For comparison the median projected reductions in the Murray Darling Basin and Tasmania are about 3 percent with no net reduction being estimated for northern Australia.


Geographic scope

• 13 surface water basins covering 39,000 km2

Presenter

Presentation Notes

The map shows location of 13 surface water basins in different group colours indicating three different regions. Rivers with highly saline flow were not included as shown by the gaps between the some of the basins. These were: the Avon, Murray River, Blackwood, and Frankland, although fresh tributaries of these were included. For Busselton Coast basin, a number of small streams discharging directly to the Southern Ocean or the Geographe Bay were modelled.


Rainfall runoff modelling

• Runoff simulated using five simple conceptual models • Sacramento• IHACRES• SIMHYD• AWBM• SMARG

• One catchment model • LUCICAT (in about half the catchments)

• The calibrated model output was compared with observed data and an average of runoff from Sacramento and IHACRES was the best

Presenter

Presentation Notes

Five simple conceptual rainfall–runoff models, and LUCICAT, which is used in many WA catchments, were used. LUCICAT is a more complicated conceptual model, only used where pre-existing calibrations were available.


Calibration results – examples

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Presenter

Presentation Notes

Annual hydrograph of observed and modelled flows and their scatter plots are shown. Calibration runs illustrate excellent fit to observed data in most cases. The points on the scatter plot lie around 1:1 line. In both of these cases the modelled runoff is slightly higher than the observed runoff in the last 5 to 6 years.


Averaged across the surface water basins 15 global climate models project less runoff

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Dry future climate -42%

Runoff change across all basins

Presenter

Presentation Notes

We are now presenting scenario modelling results This plot shows 15 global climate models runoff projection for 2030 rainfall The vertical axis shows the names of 15 GCMs. The models are ranked on the vertical axis and the estimated change in annual runoff is shown on the horizontal axis. The leftmost end of the orange bar shows the percent change in runoff due to high warming climate scenario. The right end of the green bar shows the same for the low warming scenario. The middle point, where the orange and green bars join, shows the change in runoff due to mid warming climate scenario. All models projects a lesser runoff with the median being a reduction of about 25% compared with the Historical Climate and with a range of 5 to 49 percent reduction. The symbols on the plot show runoff change for the wet and dry extremes and median future climates given by 10th, 90th and 50th percentile runoff.


Projected change in mean annual runoff relative to the historical climate

• Runoff declines by 25% under median future climate and 42% under dry climate• Proportion of area generating 110 mm runoff is: 37% under historical climate, 34% under

recent and wet future, 22% under median future, and 16% under dry future climate

Presenter

Presentation Notes

The four maps show that as the climate dries up the runoff is also decreased. Interesting to note that areas in Darling Scarp and Southern basins are affected more (in absolute terms) than inland areas. These changes may not show same pattern for the percentage change. Under the Median Future Climate, rainfall is projected to decline by an average of 8% and runoff by 25% The proportion of the area receiving more than 900mm rainfall and (on the average) producing 110 mm of runoff is: 37% under the historical climate 22% under median future climate 16% under the dry extreme future climate


Percent decline in runoff in all basins

• Decline under recent climate is greatest Gingin to Collie• Decline under median future climate more uniform across the area

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Presenter

Presentation Notes

It shows change in annual runoff in the 13 surface water basins under recent and median future climates from that under historical climate. Greatest difference between recent and median future climates is mainly in southern basins


Groundwater results

Geomorphic landforms affect groundwater response to climate change

Presenter

Presentation Notes

This map shows important features of the Perth Basin which lies to the west of the Darling Scarp. As was shown earlier, the blue Swan Coastal Plain is flat, sandy and a large part of it has been cleared for dryland agriculture. The orange area is the Gnangara Mound which has Banksia Woodland and pine plantations as important land uses, and there are high levels of abstraction from this area. The northern plateaux of Dandaragan, Arrowsmith and Yarra Yarra are elevated and contain soils which are gravelly and less sandy that the coastal plain. The Blackwood Plateau is slightly elevated and contains more clayey soils. The Scott Coastal Plain is sandy, flat and waterlogged. Some of it has been cleared, especially in the west.


Perth Regional Aquifer Modeling System

(PRAMS)

Peel Harvey Regional Aquifer Modeling

System (PHRAMS)

South West Aquifer Modeling System

(SWAMS)

Collie model

Groundwater models

• The PRAMS model as used in the Gnangara Sustainability Strategy was used

• A new model for the Peel Harvey area was developed

• The SWAMS model was linked to a recharge model and recalibrated

• The Collie model was linked to a recharge model and recalibrated

Presenter

Presentation Notes

Three groundwater models were used to estimate groundwater levels in 2030 under climate and development scenarios; Perth Regional Aquifer Modelling System or PRAMS as used in the Gnangara Sustainability Strategy but over the whole domain and with more climate scenarios A new model was developed by URS under guidance from CSIRO and DoW for the area between Mandurah and Bunbury – PHRAMS The South West Aquifer Modelling System (or SWAMS) was updated and upgraded by linking a vertical flux model to the groundwater system Likewise the Collie groundwater model was updated and upgraded. Neil Milligan from Cymod Systems helped re-calibrate the SWAMS and Collie models.


Land cover likely to affect recharge / discharge

Groundwater assessment areas

• 56% dryland agriculture

• 38% native vegetation

• 6% plantations, urban, irrigated, open water

Presenter

Presentation Notes

This map shows the main landuses over the whole project area Perennial vegetation is shown in green and cleared dryland agricultural land in bronze. The areas of pines on the Gnangara Mound, Myalup and Donnybrook Sunkland areas are shown in purple. For the Perth Basin, dryland agriculture occupies 56% and about 38% is under native vegetation. About 60% is cleared and 40% vegetated to some extent.


Maximum depth of the watertable in the southern half of the Perth Basin in 2007

• Coloured areas are potential GDEs if not cleared

• Coastal plain soils have very shallow watertables except Gnangara and Spearwood Dunes

• Plateaux areas mainly have deep watertables

22%14%10%46%

Presenter

Presentation Notes

This map shows areas in the modelled domain with a shallow watertable – green is within 3m, yellow 3 to 6m and pink, 6 to 10m. Almost half of this area has the potential to contain groundwater dependent ecosystems if they are not cleared. The Swan and Scott Coastal Plains have especially shallow watertables whereas the plateau areas (Dandaragan, Blackwood) usually have deep watertables.


Change in groundwater levels between 2008 and 2030 under climate and development scenarios

Presenter

Presentation Notes

These maps are the main groundwater findings from the project They show the change in groundwater levels between 2008 and 2030 under four climate scenarios – the historical climate (1975 to 2007), the recent climate (1997 to 2007), and the median and dry extreme future climates. If the climate of the past 33 years were to continue until 2008 groundwater levels are projected to rise under the Dandaragan Plateau, the Swan Coastal Plain near Lancelin and where the pines are removed at Gnangara and on the Swan and Scott Coastal Plains in the south. Areas under the Blackwood Plateau and the crest of the Gnangara Mound however would continue to fall. If the climate of the past 11 years were to continue until 2030 more areas would record a fall in levels but the pattern remains very similar. Under the future climate scenarios this trend continues such that under the dry extreme future climate, even removing the pines on Gnangara will not be enough to prevent groundwater levels from falling. Interestingly, groundwater levels are projected to rise under the Dandaragan Plateau even under a dry extreme future climate. This area has a relatively poorly calibrated model so this may be optimistic. However it is an area under dryland agriculture and sandy soils with modest levels of abstraction and we know that similar areas in the wheatbelt would be recording rises in groundwater levels under a annual rainfall of about 500 mm or we would not have a dryland salinity problem in the state. The Swan Coastal Plain between Perth and Bunbury changes relatively little compared with many areas. You will recall that these areas had groundwater levels within about 3 metres of the soil surface indicating that the aquifers were relatively full. It is believed that these areas are comparatively resistant to a drier climate because drainage and evaporation losses decrease as watertables fall. The lower watertables also enable more recharge to enter the aquifers. This reduction in evaporation losses will be accompanied by a loss of wetlands so there is a price to be paid for in having ‘climate resilience’. Like the Gnangara Mound, groundwater levels under the Blackwood Plateau have been falling for the last 40 or so years and this trend is projected to continue even under an historical climate. Both areas are under perennial, native vegetation and in the case of the Blackwood Plateau, the soils are clayey.


Collie groundwater basin level changes between 2008 and 2030

Groundwater levels are less affected near rivers

Presenter

Presentation Notes

Projecting future groundwater levels in the Collie Basin is difficult because there is a complex aquifer system within the sedimentary basin, heavy abstraction occurs around mine voids and for power production, groundwater inflow to voids after mining ceases and interactions between groundwater and the tributaries of the Collie River. Groundwater levels are projected to decline in the Premier Sub-basin under the Historical Climate and under almost the whole basin under the future climates. The reductions are lower near the rivers, possibly because river flows may recharge the aquifer whereas at present the rivers receive groundwater. This projection is not considered to be accurate and the new finite difference groundwater model being prepared by the Department of Water will be a better estimate of future levels.


Level of confidence in the 2030 projections of groundwater levels

• Central and Southern Perth Basin groundwater models are generally better than others

• Northern Perth Basin and Albany Area require models

• In some areas there is more confidence in specific aquifers.

• Over a 22 year period the impact on deeper aquifers is present but muted

Presenter

Presentation Notes

This maps shows how confident we are in our projections of 2030 groundwater levels. Cool colours such as dark blue show we have relatively high levels of confidence compared with the hot red colours The blue areas are mainly around Perth and the South West although the projections for the Dandaragan Plateau are low because there are few calibration bores for the PRAMS model in this area. The Peel Harvey areas has a medium to low level of confidence because the models for this area was only just constructed for the project. The model was also poorly calibrated in the Serpentine area which is shown in red. The lowest levels of confidence are for the Northern Perth Basin and Albany Areas where we don’t have any groundwater models to do the projections. The medium to high level of confidence in the Blackwood Plateau reflects confidence in the Leederville and Yarragadee levels, not the Superficial (Level 1, Mowen) projections.


Environment – key findings

For surface water dependent ecosystems• Runoff during both the wet and dry seasons is expected to

decrease by 20 to 30 percent under a median future climate• The impact of a drier climate is greater for low frequency-

high flow events, but ecosystems are less sensitive to such conditions

For groundwater dependent ecosystems• About 40% of potential GDEs may be affected to some

degree under a median future climate • There are some localised high risk areas under the dry

future climate and development scenarios

Presenter

Presentation Notes

Overall the results indicates that there is some risk which future climate and development scenarios may poss to surface water and groundwater dependent ecosystems.


Some terminology clarification

• Runoff = amount of surface water flow expressed as a depth (mm)

• Streamflow = amount of surface water flow expressed as a volume (runoff x area)

• Surface water yield = streamflow that can be diverted for use. Takes account of water for the environment and the location of nature reserves, national parks, irrigable land, etc.

• Use = water that is currently being used (metered, estimated)

• Yield = the amount of surface water and groundwater that is available for use – either under license and as unlicensed ‘stock and domestic’

• Demand – as estimate of the future requirement for water as a result of economic, demographic and industry growth. Unmet demand may result in higher water prices, reuse, water conservation, trading, desalination, etc. as well as the curtailment of growth


Water use in the project area

• Total use is about 1200 GL/y of which 71% is self supplied (on-site bores and farm dams) and three quarters is groundwater

• About 35% is used for irrigated agriculture – elsewhere in Australia it is 66 to 75%

• There is relatively little ‘low value’ agricultural water use compared with elsewhere in Australia

• Can be competition for water between water sectors – residential, industry, mining and agriculture

• The fact that so little agricultural water is in schemes, most is groundwater and it is used on high value crops, makes transfers and trading less feasible

Presenter

Presentation Notes

First some interesting facts about current water use in the project area


Yield and demand areas

• 21 surface water management areas

• 23 groundwater areas

• 8 demand regions

Perth Demand Region

Presenter

Presentation Notes

Future yields and demands were separately estimated for 21 surface water areas shown in blue, for 23 groundwater areas shown in red and for 8 demand regions shown in green. The demand regions combined surface water and groundwater yields and demands The Perth Demand Region has been highlighted as this will be shown later in the talk


Surface water use is highest in central catchments and these will grow in future

Current use = 299 GL/y Growth in demand

Presenter

Presentation Notes

Current surface water use is shown on the left hand map with areas of high use in the hotter colours. The units are ML per square kilometre per year, or mm – as has been used in previous maps to take account of the different sizes in the areas shown. Interestingly, the highest use per unit of catchment area is in the central basins around Dandalup, Harvey and Collie. Growth in demand for surface water is shown in the other two maps. Under both the medium and high growth in demand scenarios, the estimated demand pressures are highest in the central basins as well as the Warren. These are all horticultural areas and the growth in demand estimates result from assumed increases in demand for surface water to help meet the demands fro horticultural products by a growing population and economy.


Current surface water yields

Total yield = 425 GL/y

Licensed allocations

• Public Water Supply 24%

• Irrigation schemes 27%

• Self supply 49%

• Harvey and Collie contribute 43% of total yield

Presenter

Presentation Notes

These maps show surface water yields – or the amount of water than can be safely diverted for use – in two ways The left map shows yields in volumes per year from each of the 13 basins while the right map show them in ML per square kilometer per year (or mm per year) The highest yielding basins are in the centre with those to the north and south with low yields, either because there is little streamflow (north) or because the streamflow may be within areas that contain nature reserves or national parks (south) as well as having lower streamflows per area. The total yield of all basins is about 425 GL/yr with about 43% of this coming from the central Harvey and Collie Basins. Currently surface water is used by self-supply irrigators with dams on streams within their property (about half), and by irrigation schemes (mainly Harvey Water) and public water supply dams which each use about a quarter.


Surface water yields are projected to change by -24% under a median future climate. Range of -4 to -49%

IWSS yields reduced by 18% to 77 GL/y under a median future climate

Presenter

Presentation Notes

These three maps show the projected percentage change in surface water yields under three climate scenarios – a continuation of the Recent Climate, the Median Future Climate and the Dry Future Climate Under the Median Future Climate, surface water yields are estimated to decrease by about 24% compared with the Historical Climate with the range being between 4% (under the Wet Future Climate) and 49% decrease (under the Dry Future Climate). The projected future reductions in yields are not uniform across all basins. Interestingly the high yielding Harvey and Collie Basins also appear to have lower reductions compared with basins to both the north and south. The Gingin, Donnelly, Warren and Denmark catchments appear to be most affected. The estimated reduction in 2030 yield to the metropolitan dam catchments which supply water to the Integrated Water Supply Scheme is 18% or 77 GL/y. These estimates are very similar to those in Water Corporation’s Water Forever plan


Selected water yield areas

More detailed data are available for runoff (mm) and streamflows (GL/y)

Surface water management area Current Median Future

ClimateDry Extreme Future

ClimateGL/y GL/y % change GL/y % change

Helena 9.6 7.9 -18 3.9 -59

Canning River 25.4 21.1 -17 14.8 -42

Serpentine River Catchment

20.7 15.6 -25 9.1 -56

Dandalup River System

21.9 15.8 -28 9.6 -56

Collie 93.6 72.9 -22 53.8 -43

Total 171.2 133.3 -22 91.2 -47

Presenter

Presentation Notes

This slide shows the estimated yield reductions under a median and extreme dry future climate in catchments that provide water to the IWSS. The numbers are similar to the SWSY estimates overall – about a quarter reduction under the median climate and a halving under the dry future climate. The Canning River catchment may be slightly less affected.


Gaps in surface water yields and demands in areas where irrigation is important

DeficitSurplus

Presenter

Presentation Notes

Having estimated future demands and yields it is possible to map gaps between them. A positive gap represents a surplus of water – shown here in cool colours, and a negative gap is a potential deficit of water – shown here in hot colours. Under the Median and Dry Future Climates, surface water deficits are evident in the Harvey and Dandalup Basins. Deficits are apparent wherever horticultural demand is expected to grow by 2030 and yields are projected to decline.


Current groundwater yields as estimated by adding the 2009 Allocation Limits

Total yield Yield per unit area Total yield = 1556 GL/y

Main aquifers:

• Superficial 58%

• Leederville 12%

• Yarragadee 26%

Presenter

Presentation Notes

To estimate current groundwater yields we added all of the allocation limits for all aquifers in each groundwater area. The total yield of these aquifers was 1,556 GL per year with 58% contained in the Superficial Aquifer,12% in the Leederville and 26% in the Yarragadee The left map shows the yields in GL per groundwater area and the right map in ML per square kilometer per year or mm per annum. The highest yielding areas shown in blue on the right map are located around Perth and in the SW Coastal area around Preston. These areas have multiple aquifers which are high yielding – over 200 mm per annum being able to be abstracted. In comparison the aquifers in the northern and southern Perth Basins, and near Albany, are much lower yielding as defined by this method. Perth is very fortunate to have been located in a water-rich area. Its is also possible that the resources in this area of high demand have been more fully investigated and exploited and therefore they appear relatively high.


Groundwater use and future demand is highest near Perth and Bunbury

Current use = 808 GL/y (2.2 x surface water)

Perth – Peelarea

Bunbury

Additional

Growth in demand

Presenter

Presentation Notes

The map on the left shows current groundwater use reflects the current water yield map that was just shown with high concentrations near Perth and around Bunbury and Collie. Everything ‘hotter’ than yellow has an annual use of more than 50 mm per annum. The other two maps show the expected growths in demand for groundwater under medium and high demand scenarios. Future growth in demand for groundwater is expected to be substantial near Perth and Bunbury with demand growing by 25 to 50 % of current use in these areas. This does not mean that all of this demand will be met but it does show that there may be requirements for increased efficiencies of use, other water sources may need to be developed or imported and there may be significant unmet demand.


Groundwater yields are projected to change by -2% under a median future climate. Range = +2 to -7%

Yield reductions are low because1. Drain and ET losses reduce as watertables fall 2. Areas under dryland agriculture (56% of Perth Basin) have rising levels3. Allocation Limits account for a future drier climate

Recentclimate

Median future climate

Dryfuture climate

Presenter

Presentation Notes

Using this method it was estimated that future groundwater yields would decrease by about 2% under the Median Future Climate with a range of +2% under a Wet Future Climate to a decrease of about 7% under a Dry Future Climate. Areas with the greatest decreases in yield were Gnangara, the Blackwood, Collie groundwater basin and the Albany Area All of these areas are overlain by perennial vegetation which reduces recharge compared with cleared dryland agricultural land, the areas where yields were less affected. While the average reduction in groundwater yields is relatively small, some resources have substantial projected decreases under the Dry Future Climate – e.g. by between a quarter and a half for the four areas just mentioned


Presenter

Presentation Notes

This image show that there are large parts of the Perth Basin that are under dryland agriculture which allows seasonal recharge to underlying aquifers. Small areas may be irrigated to use this additional water as shown in this image of the Perth Basin west of Moora.


IWSS yield and demands

Presenter

Presentation Notes

A separate yield and demand region was defined for the IWSS in the YGAP spreadsheet.


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116 GL/y

Demand Historical Recent Wet extreme Median future Dry extremeGL/y

Low demand -47 -73 -55 -86 -125Medium demand -77 -103 -85 -116 -155High demand -136 -162 -144 -175 -214

Presenter

Presentation Notes

The estimated demands were taken from Water Forever (2009) Surface water (teal colour) was estimated to decrease from 95 to 77 GL/y (18%) which is very similar to Water Forever (75 GL/y) Groundwater yields were not calculated as being much affected (145 to 142 GL/y or -2%) compared to 90 GL/r under Water Forever. Most of the losses are in eth Superficial Aquifer (light green) However the 2% includes groundwater resources which are estimated to have increased net recharge because of being under dryland agriculture, post pines, urbanised or reduced drainage and evapotranspiration/ Some of these increased yields may not be available to the IWSS because of competition from LGAs, backyard bores, peri-urban agriculture, industry etc. A water deficit of 116 GL/y was estimated for 2030 under a medium future climate and a medium demand. Efficiency gains, a second desalination plant and other measures outline in Water Forever may reduce this gap to 41 GL/y under a Median Future Climate and to 80 GL/y under a Dry Extreme Future Climate by 2030. The Water Forever deficit is estimated to be 70 GL/y. Once the assumptions are taken into account the estimates by both projects are therefore comparable


Groundwater deficits may develop near Perth, Collie and Albany

Recent climate 2030 gap

Median future climate2030 gap

Dry future climate2030 gap

Surplus

Deficit

Presenter

Presentation Notes

This slide shows surpluses in blue and deficits in ‘hot colours’ under three scenarios – Recent Climate, Median Future Climate and Dry Future Climate The main groundwater deficits are expected to develop near Perth, Collie and Albany A limitation of the method used to estimate future water demands is that new industries are not included in the estimates of growth, e.g. a paper pulp mill or a new mine. It is therefore feasible that the apparent surplus of water in the Northern Perth Basin may be used if demands by mid-west iron ore companies eventuate. These demands can be incorporated into the method that was developed by this project if the demands are known, but they were not been included in this analysis.


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Mirrabooka

Leederville

Superficial

Other aquifer

Self-supply dams

Scheme dams

Fractured rock

The project area can meet all except high demands until 2030 under a median future climate

• A 250 GL/y deficit may develop under a dry extreme climate and high demand

250 GL

Presenter

Presentation Notes

These graphs show the yield and demand gaps for the entire project area. The decrease in surface water yields is very apparent in the left graph, along with a substantial decrease in yields in the Superficial Aquifer. Groundwater, which currently supplies about three quarters of all water needs, may become even more important in future, along with other water sources such as desalination and water reuse. The right graph shows how both demand and yields are projected to change between 2008 and 2030. If there is median grown in demand and a Median Future Climate, there is enough water to meet all growth in existing industries until 2030. This assumes that water quality is adequate and transportations cost are not prohibitive. This situation is possible largely because of the large groundwater reserves that are contained within the Perth Basin. In reality there will be local deficits and alternative sources will be developed, as is occurring already through desalination, and there will be an increasing need for increased water efficiencies, reuse and trading. If we experience a Dry Future Climate and demand growth is high there could be a 250 GL per year deficit by 2030. Obviously these estimates are approximate only and are based on a set of assumptions which affects estimates of both future yields and demands. This project has developed some tools that could be adapted and used over time as both data and assumptions are improved.


Key Findings

1. South-west Western Australia has experienced a significant shift since 1975 which probably contains a component of climate change. Climate models project that the region will get about 7% drier by 2030 (could be up to 14%)

2. Surface water yields have already decreased in northern catchments and may decrease further by 2030. Central catchments are higher yielding and could decrease by less. Southern catchments are lower yielding and may decrease by most in volume. The overall decrease may be about 24% but it could be up to 49%


Key Findings (cont.)

3. Groundwater levels are projected to fall most under areas of perennial vegetation, e.g. Gnangara, Blackwood Plateau, Collie and Albany.

Levels are least affected in areas with high watertables such as coastal areas under dryland agriculture, e.g. Swan and Scott Coastal Plains; Dandaragan Plateau

As watertables fall, drainage and evaporation from GDEs fall and allows more recharge to enter

4. Water dependent ecosystems have already been impacted and these impacts are projected to worsen, especially for high streamflows and GDEs with a watertable depth of 6 to 10m


Key Findings (cont.)

5. Water deficits between yields and demands are likely in:• Surface water irrigation catchments• Aquifers near Perth, Collie and Albany

6. Overall there is enough water to meet all except high demands under a median future climate. However if there is a dry extreme climate and a high demand the deficit may be as much as 250 GL/y


Acknowledgements

• DEWHA – funding and policy guidance• Department of Water – data, models, researchers, report review• Water Corporation – data, report review – Mike Canci, Charles Jeevaraj,

Chengchao Xu• Department of Agriculture and Food WA – soils data • Bureau of Meteorology – climate data, surface water modelling• Queensland Department of Environment and Resource Management – SILO data• Contracts and consultancies

• URS – Peel Harvey groundwater model• CyMod Systems Pty Ltd – groundwater model calibration• Resource Economics Unit – demand estimation• Geographic Information Analysis – model data preparation• Jim Davies and Associates – yield and demand analyses

• External reviewers: Peter Davies (University of Tasmania); Andy Pitman (University of New South Wales); Tony Jakeman (Australian National University): Don Armstrong (Lisdon Associates) and Murray Peel (University of Melbourne)

Presenter

Presentation Notes

It is important to acknowledge the very substantial contributions made by people and groups outside CSIRO DEWHA provided funding and policy guidance; the DoW provided significant assistance from the provision of data and models to being partners in the research and review – about 25 DoW people had some input. Water Corp, DAFWA and the Bureau of Met provided data and technical assistance; SILO data were used in the modelling. Five consulting groups were used to provide important technical input as shown in the slide. Finally the results and reports underwent extensive review – internally, with the DoW and Water Corporation; then through a national Technical Reference Panel and also an external group of reviewers as shown on the slide. As a result, hundreds of suggestions were incorporated into each of the three main reports.


Contributors

Project Director Tom HattonSustainable Yields Coord. Mac KirbyProject Leader Don McFarlaneProject Support Frances Parsons, Therese McGillion, Paul Jupp, Josie GraysonData Management Geoff Hodgson, Jeannette Crute, Christina Gabrovsek, Mick Hartcher, Malcolm Hodgen

DOW – Aidan BelouardiDAFWA – Damien Shepherd, Dennis van Gool, Noel Schoknecht

Climate Stephen Charles, Francis Chiew, Randall Donohue, Guobin Fu, Ling Tao Li, Steve Marvanek, Tim McVicar, Ian Smith, Tom Van NielNSW Dept of Water and Energy – Jin Teng

Surface Water Richard Silberstein, Santosh Aryal, Neil Viney, Ang YangDOW – Mark Pearcey, Jacqui Durrant, Michael Braccia, Kathryn Smith, Lidia Boniecka, Simone McCallumBOM – Mohammad BariGeographic Information Analysis – Geoff Mauger

Groundwater Riasat Ali, Warrick Dawes, Sunil Varma, Irina Emelyanova, Jeff Turner, Glen Walker, John Byrne, Phil Davies, Steve Gorelick, Mahtab AliDOW – Chris O’Boy, Binh Anson, Phillip Commander, Cahit Yesertener, Jayath de Silva, Jasmine Rutherford Water Corporation – Mike Canci, Chengchao XuCymod Systems – Neil MilliganURS Australia – Wen Yu, Andrew Brooker, Amandine Bou, Andrew McTaggart

Water Yields and Demands Olga Barron, Natalie Smart, Michael DonnDOW – Roy Stone, Phillip Kalaitzis, Rob Donohue, Fiona Lynn, Adrian Goodreid, Andrew Paton, Susan Worley, Kylie La SpinaResource Economics Unit – Jonathan ThomasJim Davies and Associates – Sasha Martens, Kate Smith

Reporting Viv Baker, Becky Schmidt, Susan Cuddy, Simon Gallant, Heinz Buettikofer, Elissa Churchward, Chris Maguire, Linda Merrin

Communications Anne McKenzie, Helen Beringen, Mary Mulcahy


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