Irrigation in Australia

Last updated

Centre pivot irrigation near Euberta in the Riverina region of New South Wales EubertaCentrePivotIrrigation.jpg
Centre pivot irrigation near Euberta in the Riverina region of New South Wales

Irrigation is a widespread practice required in many areas of Australia, the driest inhabited continent, to supplement low rainfall with water from other sources to assist in growing crops and pasture. [1] Overuse or poor management of irrigation is held responsible by some for environmental problems such as soil salinity and loss of habitat for native flora and fauna. [2]

Contents

Irrigation differs from dryland farming (farming relying on rainfall) in Australia in its level of intensity and production. It is a far more economically productive land use than dryland farming. [3] Common crops produced using irrigation include rice, cotton, canola, sugar, various fruits, and other tree crops, and pasture, hay, and grain for beef and dairy production. Surface irrigation is Australia's most common irrigation method, with drip and center pivots also utilised. All rights to use and control water are vested in the state, which issues conditional entitlements for water use.

The first large-scale irrigation schemes in Australia were introduced during the 1880s, partially in response to drought. In 1915, the River Murray Waters Agreement was signed, setting out basic conditions for the river's water use which remain in force today. Towards the end of the 20th century, environmental problems in the basin became serious as diversions for irrigation approached or exceeded the capacity of natural flows. Following negotiations beginning in 1985, the Murray–Darling Basin Agreement was signed in 1987. The more comprehensive National Water Initiative was adopted in 2004.

Water sources

A diesel irrigation pump in Mildura, Victoria. Diesel pump irrigation.jpg
A diesel irrigation pump in Mildura, Victoria.

In general, water for irrigation comes from two main sources: river systems and underground aquifers. Major river systems used for irrigation in Australia include the Murray-Darling system, the Ord River in the Kimberley region of Western Australia, and many rivers along the east coast of Australia, including the Burdekin River Irrigation Area in North Queensland, where irrigation is used during the dry season for double-cropping. [4] A major source of groundwater in Australia is the Great Artesian Basin.

Although the Murray-Darling Basin receives only 6% of Australia's annual rainfall, over 70% of Australia's irrigation resources are concentrated there, which makes up around 90% of the resources in the basin. It contains 42% of the nation's farmland and produces 40% of its food.[ citation needed ]

History

Irrigation in New South Wales during the 1920s SLNSW 920634 Series 09 Irrigation ca 19211924.jpg
Irrigation in New South Wales during the 1920s

The first schemes for irrigation commenced in the latter half of the nineteenth century. Goulburn Weir, constructed from 1887 to 1891, was the first major diversion structure built for irrigation development in Australia. [5]

Memorial marking the site of the first commercial rice crop in the Murray valley at Tullakool, New South Wales TullakoolMemorial.JPG
Memorial marking the site of the first commercial rice crop in the Murray valley at Tullakool, New South Wales

A major drought in Victoria from 1877 to 1884 prompted Alfred Deakin, then a minister in the State Government and chairman of a Royal Commission on water supply to visit the irrigation areas of California. There, he met the Canadian brothers George and William Chaffey, who had worked on irrigation schemes in California. [6] In 1886, the Chaffey brothers came to Australia and selected a derelict sheep station covering 250,000 acres (1,000 km2) at Mildura as the site for their first irrigation settlement. [6] They signed an agreement with the Victorian government to spend at least 300,000 on permanent improvements at Mildura in the next twenty years. Also in 1886/87, the Chaffey brothers were invited by John Downer, the Premier of South Australia, to commence a settlement at Renmark, South Australia. [7]

The Dethridge wheel, used for measuring the flow of water delivered to individual farms was developed in 1910. [8]

Artesian bore near Barcaldine in Queensland, 1924 StateLibQld 2 212324 Artesian bore near Barcaldine, Queensland, 1924.jpg
Artesian bore near Barcaldine in Queensland, 1924

Irrigation in the Murrumbidgee valley began with the irrigation experiments of agricultural pioneer, Samuel McCaughey at North Yanco station in 1900. This private scheme involved the construction of around 320 kilometres of channels in irrigating about 162 square kilometres (63 sq mi) of land. [9] McCaughey's success appeared to have encouraged the New South Wales government to commence large-scale irrigation. This process began in 1906 with the Barren Jack and Murrumbidgee Canals Construction Act 1906 (Cth) proclamation. Burrinjuck Dam on the Murrumbidgee River near Tumut was commenced in 1907, work commenced on the channels and the first farms were established soon after.

In 1907, the Victorian government invited American Elwood Mead to become chairman of the newly formed State Rivers and Water Supply Commission of Victoria. The high hopes for government-controlled irrigation in Victoria owed much to Deakin's earlier efforts, who now as Prime Minister, expected Mead to advise at both national and state levels. Mead was not content with proposing only higher water rates in attempting to recover maintenance, management, and construction costs. He also insisted on the logical extension, which demanded higher-yielding uses of water and land. The Water Act of 1909 was passed despite the fierce opposition of large landowners, and Mead's influence on rural development was greatly increased by his assumption of overriding control in the planning of closer settlement in Victoria's irrigation districts. Mead claimed much credit for the hierarchical arrangement of allotment sizes which characterized these designs, but his impact was rather in the very scale and complexity of the commission's operations, in Mead's salesmanship, and in the bureaucratic web in which the new settlers became enmeshed. Mead worked in Australia full-time for four years, but his involvement would continue until his resignation became effective in May 1915; this professional experience consolidated Mead's international reputation. In 1923, Mead's four-month Australia advisory tour was punctuated by disputes with Joseph Carruthers and leading irrigation authorities in New South Wales over the selection and use of land in the Murrumbidgee Irrigation Area. Mead rejected plans for further fruit planting, advocating larger dairy farms and improved co-ordination of grazing and irrigation enterprises, which would favour stock fattening and the intensive production of lucerne. [10]

In Western Australia, the state's first controlled irrigation scheme, the Harvey Irrigation Scheme, was officially started in 1916. It was further developed during the latter part of the 1930s depression to take unemployed workers to dig and build the extensive irrigation channels in the district. [11]

Policy

The management of irrigation, particularly with relation to the problems of the Murray-Darling Basin has long been a politically contentious issue in Australia.

The River Murray Waters Agreement

Regulation of the Murray River system was one of the first issues addressed after Federation. A period of drought beginning in 1895 culminated in the 'Federation drought' of 1901–2. One result was a non-government conference held in Corowa in 1902, which called for government action to manage the waters of the Murray River. [12] A prolonged period of negotiation followed, during which the states claimed property rights over the waters of the Murray and its tributaries.

The upstream states, Victoria and New South Wales, favoured the riparian doctrine, under which landowners are free to take water from streams flowing through their property. As the 'Premier State', New South Wales, claimed riparian rights not only over its own rivers, but over the entire main stream of the Murray. South Australia relied on provisions of the newly enacted Constitution under which the Commonwealth government had authority over navigation along the Murray River and an implied obligation to preserve flows in the South Australian section of the river.

Negotiations were finally concluded in 1915. [12] The River Murray Waters Agreement, to which the Commonwealth and the states of New South Wales, Victoria and South Australia were parties, set out the basic conditions which remain in force today:

The agreement also provided for construction of dams, weirs and locks on the main stream of the Murray to be managed by the River Murray Commission, which was established in 1917.

Although it was an important example of cooperative federalism, the River Murray Waters Agreement was limited to the management of water for irrigation and navigation.

The Murray–Darling Basin Agreement

As diversions for irrigation approached or exceeded the capacity of the Murray–Darling river system, and environmental problems became more serious, the need for a coordinated approach to management of the Basin as a whole became more evident. Following negotiations beginning in 1985 the Murray–Darling Basin Agreement was signed in 1987. In its initial form, it was as an amendment to the River Murray Waters Agreement. Five years later, in 1992, a totally new Murray–Darling Basin Agreement was signed, replacing the River Murray Waters Agreement. The Agreement was given full legal status by the Murray–Darling Basin Act 1993 which was passed by all the contracting governments. Queensland and the Australian Capital Territory later joined the agreement.

The stated purpose of the Murray–Darling Basin Agreement was 'to promote and coordinate effective planning and management for the equitable, efficient and sustainable use of the water, land and other environmental resources of the Murray–Darling Basin'

To achieve this, the Agreement established new institutions at the political, bureaucratic and community levels. These were:

The National Water Initiative

The lack of satisfactory progress under the Murray–Darling Basin Agreement and the emergence of a variety of water policy problems elsewhere in Australia led to the adoption of the National Water Initiative in 2004. Key elements of the Initiative included promotion of water trading and a commitment to restore at least 500 gigalitres of environmental flows to the Murray Darling Basin

Production

Close up of an Impact (Knocker) Sprinkler in use on a fodder crop Impact(Knocker)IrrigationCloseUp.jpg
Close up of an Impact (Knocker) Sprinkler in use on a fodder crop

Water consumption by the agriculture industry was 12,780 gigalitres (2,810×10^9 imp gal; 3,380×10^9 US gal) in 2012-13, accounting for 65% of total water consumption in Australia during that period. Irrigation/rural water providers were the main suppliers of distributed water in 2004-05 accounting for 6,637 gigalitres (1,460×10^9 imp gal; 1,753×10^9 US gal) or 59% of Australia's total distributed water supply. [13] Since 2005 climatic conditions and reduced allocations have caused the total water consumed to decline by 30% from the 2004-2005 figure down to 8,521 gigalitres (1,874×10^9 imp gal; 2,251×10^9 US gal) in 2006-2007 [14] and further to 7,286 gigalitres (1,603×10^9 imp gal; 1,925×10^9 US gal) in 2008-2009. [15] The total gross value of irrigated agricultural production in 2012-13 was A$13,431 million [16] up from A$9,076 million in 2004-05 and A$9,618 million in 2000-01. [13] The gross value of irrigated agricultural production represents around a quarter (23%) of the gross value of agricultural commodities produced in Australia in 2004-05, on less than 1% of agricultural land. [17]

Common crops produced using irrigation include rice, cotton, canola, sugar, various fruits and other tree crops and pasture, hay and grain for use in beef and dairy production.

Gross value of irrigated
agricultural production [13] [16] 		2000-01
A$M		2004-05
A$M		2012-13
A$M
Dairy farming1,4991,6321,908
Vegetables1,8171,7612,746
Sugar284477599
Fruit1,5901,7772,801
Grapes1,3551,3141,074
Cotton1,2229081,789
Rice350102302
Nurseries, cut flowers & turf763737845
Livestock, pasture, grains & other737367
Total9,6189,07613,431

Cotton

Major cotton growing areas in Australia are:

In 2001/02 crop size was 420,170 hectares (1,038,300 acres) producing 3,041,000 bales . Estimates for 2006/07 were for 142,032 hectares (350,970 acres) producing cotton, a 66% reduction, producing a forecast crop of 1,171,765 bales, a 61% reduction. [18] The total gross value of irrigated agricultural production in the cotton industry in 2004-05 was A$908 million compared to A$1,222 million in 2000-01. While demand skyrocketed, actual water use by the cotton industry fell by 37% between 2000/01 and 2004/05, due mainly to drought. [13] [19] The cotton industry used 2,896 gigalitres (637×10^9 imp gal; 765×10^9 US gal) in 2000/01, 1,822 gigalitres (401×10^9 imp gal; 481×10^9 US gal) in 2004/05 [17] and 793 gigalitres (174×10^9 imp gal; 209×10^9 US gal) in 2008/09. [15]

Rice

Irrigated areas in the Riverina produces the vast majority of rice grown in Australia, particularly in the Murrumbidgee Irrigation Area (MIA), but also the Murray Irrigation Area around Finley, Coleambally and Deniliquin areas. [20]

Today, more than one million tonnes of Australian rice is produced each year and exported to over 70 countries, generating A$500 million in export income and supporting 63 towns in the Riverina and northern Victoria. [21] Major rice mills are located in Leeton, Coleambally and the largest rice mill in the southern hemisphere in Deniliquin. [22]

The total gross value of irrigated agricultural production in the rice industry in 2004-05 was A$102 million compared to A$350 million in 2000-01. Water use by the rice industry fell between 2000/01 and 2004/05, due mainly to smaller planted areas during the drought; the rice industry used 2,223 gigalitres (489×10^9 imp gal; 587×10^9 US gal) in 2000/01, 631 gigalitres (139×10^9 imp gal; 167×10^9 US gal) in 2004/05 [13] [17] and 101 gigalitres (22×10^9 imp gal; 27×10^9 US gal) in 2008/09. [15]

Grapes

Wine, dried and table grapes are grown commercially in all states and territories. Grape production is now the largest fruit industry in Australia. [23] Of that production wine grape production at over 1 million tonnes (980,000 long tons; 1,100,000 short tons) per annum is almost nine times the production of dried grapes and 14 times the production of table grapes.

A comparison with other grape producing countries throughout the world shows that Australia was the fourteenth largest producer of grapes in 1997.

Towards sustaining that production much of Australia’s viticulture is located in irrigable areas where water supply is reliable and well managed, with many new vineyards relying upon the availability of water pumped from rivers and streams.

The Australian grape industry used a total of 439 gigalitres (97×10^9 imp gal; 116×10^9 US gal) in 2006/07, equating to approximately 4.3 ML/ha. [15]

Major grape growing areas of Australia are:

Water trading

In Australia, all rights to use and control water are vested in the states. Users are then issued various conditional entitlements to use water and some of these entitlements can, in limited circumstances, be traded.

Entitlements vary state by state and according to the use, source, legal form, level of devolution, security and transferability among others. There has been a move across all states in recent years to move from older forms of water entitlement to more secure and transferable entitlements. Key parts of this move has been the separation of water entitlements from ties to particular parcels of land and the specification of entitlements with specific volumes and reliability.

Where an entitlement is able to be traded, the transaction may take several forms including temporary transfer of a seasonal water assignment, a permanent transfer of all or part of a water entitlement or a lease over a set period of years. All transfers require approval from the various regulatory bodies to ensure it complies with trading rules designed to meet environmental and in some cases socio-economic objectives. Such rules may include approving trades only within a set zone or the exchange rate of trades between zones to reflect water losses in delivery or differences in reliability. [25]

Methods

The Riverina Irrigation Channel, 2010 Irrigation Channel in the MIA.jpg
The Riverina Irrigation Channel, 2010

Irrigation methods in Australia have improved over many years allowing for more efficient production per megalitre of water used. Current methods include systems such as centre pivot irrigation, impact (knocker) sprinklers, butterfly sprinklers, drip and surface irrigation. Surface irrigation remains the most common irrigation technique accounting for 58.6% of the total area irrigated in 2013/14 compared to 10.8% for drip, 13.2% for centre pivot and lateral move machines and 4.4% for microspray systems. [26] These values may change from season to season due to water availability and commodity prices.

Furrow irrigation is the typical choice for row crops such as cotton, sugar-cane and grains. Border-Check irrigation is the dominant technique for irrigating pasture. Centre pivots and lateral move machines are also used within row cropping and pasture/fodder crops and offer higher levels of control than furrow irrigation. Smaller scale sprinkler systems such as solid set systems with impact sprinklers are commonly used to grow vegetables and turf. Drip systems are found within most of the high value perennial horticultural crops such as grapes and fruit trees.

Centre pivot irrigation is often used for crops where the water can be distributed over a considerable period of time. In other crops where moisture stress is a complex concern, for example during the growing of cauliflower, water is required to be distributed quickly two or three specific times per day at a rate of about 140% the evaporation replacement rate and for this impact sprinklers set every 12 square metres or butterfly sprinklers set every 6 square metres are required. [27] Drip sprinklers can be used on many spaced planting locations but typically will be found as gravity fed systems on vineyards.

Most if not all farms employ earthworks such as laser levelling to facilitate drainage and improve water use efficiency and uniformity.

Environment

A simplified depiction of the process of increased salinity from irrigation Salinity from irrigation.png
A simplified depiction of the process of increased salinity from irrigation

Overuse and poor irrigation practices have led to increased salt content in the soil, reducing the productivity of the land. Irrigation salinity is caused by water soaking through the soil level adding to the ground water below. This causes the water table to rise, bringing dissolved salts to the surface. As the irrigated area dries, the salt remains. [2] At Wakool in the Riverina region of New South Wales, irrigation salinity is mitigated through a salt interception scheme that pumps saline ground water into evaporation basins, protecting approximately 50,000 hectares of farmland in the area from high water tables and salinity. The subsequent salt has various uses including as an animal feed supplement. The program has returned to production over 2,000 hectares of previously barren farmland and encouraged the regeneration of native eucalypts. [28]

See also

Related Research Articles

<span class="mw-page-title-main">Irrigation</span> Agricultural artificial application of water to land

Irrigation is the practice of applying controlled amounts of water to land to help grow crops, landscape plants, and lawns. Irrigation has been a key aspect of agriculture for over 5,000 years and has been developed by many cultures around the world. Irrigation helps to grow crops, maintain landscapes, and revegetate disturbed soils in dry areas and during times of below-average rainfall. In addition to these uses, irrigation is also employed to protect crops from frost, suppress weed growth in grain fields, and prevent soil consolidation. It is also used to cool livestock, reduce dust, dispose of sewage, and support mining operations. Drainage, which involves the removal of surface and sub-surface water from a given location, is often studied in conjunction with irrigation.

<span class="mw-page-title-main">Snowy Mountains Scheme</span> Dam in Kosciuszko National Park, New South Wales

The Snowy Mountains Scheme, also known as the Snowy Hydro or the Snowy scheme, is a hydroelectricity and irrigation complex in south-east Australia. Near the border of New South Wales and Victoria, the scheme consists of sixteen major dams; nine power stations; two pumping stations; and 225 kilometres (140 mi) of tunnels, pipelines and aqueducts that were constructed between 1949 and 1974. The Scheme was completed under the supervision of Chief Engineer, Sir William Hudson. It is the largest engineering project undertaken in Australia.

<span class="mw-page-title-main">Darling River</span> Major river in Australia

The Darling River is the third-longest river in Australia, measuring 1,472 kilometres (915 mi) from its source in northern New South Wales to its confluence with the Murray River at Wentworth. Including its longest contiguous tributaries it is 2,844 km (1,767 mi) long, making it the longest river system in Australia. The Darling River is the outback's most famous waterway.

<span class="mw-page-title-main">Murray–Darling basin</span> Largest Australian river catchment

The Murray–Darling Basin is a large geographical area in the interior of southeastern Australia, encompassing the drainage basin of the tributaries of the Murray River, Australia's longest river, and the Darling River, a right tributary of the Murray and Australia's third-longest river. The Basin, which includes six of Australia's seven longest rivers and covers around one-seventh of the Australian landmass, is one of the country's most significant agricultural areas providing one-third of Australia's food supply. Located west of the Great Dividing Range, it drains southwest into the Great Australian Bight and spans most of the states of New South Wales and Victoria, the Australian Capital Territory, and parts of the states of Queensland and South Australia.

<span class="mw-page-title-main">Balonne River</span> River in Queensland, Australia

The Balonne River, part of the Murray-Darling Basin system, is a short yet significant part of the inland river group of South West Queensland, Australia.

<span class="mw-page-title-main">Goulburn River</span> River in Victoria, Australia

The Goulburn River, a major inland perennial river of the Goulburn Broken catchment, part of the Murray-Darling basin, is located in the Alpine, Northern Country/North Central, and Southern Riverina regions of the Australian state of Victoria. The headwaters of the Goulburn River rise in the western end of the Victorian Alps, below the peak of Corn Hill before descending to flow into the Murray River near Echuca, making it the longest river in Victoria at 654 kilometres (406 mi). The river is impounded by the Eildon Dam to create Lake Eildon, the Eildon Pondage, the Goulburn Weir and Waranga Basin.

<span class="mw-page-title-main">Snowy River</span> River in south-eastern Australia

The Snowy River is a major river in south-eastern Australia. It originates on the slopes of Mount Kosciuszko, Australia's highest mainland peak, draining the eastern slopes of the Snowy Mountains in New South Wales, before flowing through the Alpine National Park and the Snowy River National Park in Victoria and emptying into Bass Strait.

<span class="mw-page-title-main">Avoca River</span> River in Victoria, Australia

The Avoca River, an inland intermittent river of the north–central catchment, part of the Murray-Darling basin, is located in the lower Riverina bioregion and Central Highlands and Wimmera regions of the Australian state of Victoria. The headwaters of the Avoca River rise on the northern slopes of the Pyrenees Range and descend to flow into the ephemeral Kerang Lakes.

<span class="mw-page-title-main">Riverina</span> Region in New South Wales, Australia

The Riverina is an agricultural region of south-western New South Wales, Australia. The Riverina is distinguished from other Australian regions by the combination of flat plains, warm to hot climate and an ample supply of water for irrigation. This combination has allowed the Riverina to develop into one of the most productive and agriculturally diverse areas of Australia. Bordered on the south by the state of Victoria and on the east by the Great Dividing Range, the Riverina covers those areas of New South Wales in the Murray and Murrumbidgee drainage zones to their confluence in the west.

<span class="mw-page-title-main">Waranga Dam</span> Dam in North Central region, Victoria

The Waranga Dam is a major earthfill embankment dam with an uncontrolled spillway located approximately 150 kilometres (93 mi) north of Melbourne in the North Central region of the Australian state of Victoria. The impounded off-stream reservoir is Waranga Basin and forms part of the Goulburn River irrigation system, irrigating an area of 626 square kilometres (242 sq mi). The dam and reservoir are located in Shire of Campaspe near the City of Greater Shepparton and is located 8 kilometres (5 mi) north-east of Rushworth, 12 kilometres (7.5 mi) south-west of Tatura, and near Murchison. When full, the reservoir covers an area of 58.5 square kilometres (22.6 sq mi).

<span class="mw-page-title-main">Goulburn Valley</span>

The Goulburn Valley is a sub-region, part of the Hume region of the Australian state of Victoria. The sub-region consists of those areas in the catchment of the Goulburn River and other nearby streams, and is part of the Murray-Darling Basin. The Goulburn Valley is bordered on the south by the Great Dividing Range and to the north by the Murray River, the state border with New South Wales. The sub-region is one of Australia's most productive and intensively farmed areas and is predominantly irrigated.

<span class="mw-page-title-main">Murrumbidgee Irrigation Area</span> Food production system in south east Australia

<span class="mw-page-title-main">Coleambally</span> Town in New South Wales, Australia

Coleambally is a small town in the Riverina of New South Wales, Australia, in Murrumbidgee Local Government Area.

<span class="mw-page-title-main">Eucumbene Dam</span> Dam in Snowy Mountains, New South Wales

Eucumbene Dam is a major gated earthfill embankment dam with an overflow ski-jump and bucket spillway with two vertical lift gates across the Eucumbene River in the Snowy Mountains of New South Wales, Australia. The dam's main purpose is for the generation of hydro-power and is one of the sixteen major dams that comprise the Snowy Mountains Scheme, a vast hydroelectricity and irrigation complex constructed in south-east Australia between 1949 and 1974 and now run by Snowy Hydro.

<span class="mw-page-title-main">William Hovell Dam</span> Dam in Hume, Victoria

The William Hovell Dam is a rock and earth-fill embankment dam with a flip bucket chute spillway across the King River, operated by Pacific Blue and located in the Hume region of Victoria, Australia. The purposes of the dam are for irrigation and the generation of hydroelectricity. The impounded reservoir is called Lake William Hovell.

<span class="mw-page-title-main">Renmark Paringa Council</span> Local government area in South Australia

The Renmark Paringa Council is a local government area located adjacent to the Victorian border, in the Riverland, South Australia. The area is known for its various fruit production, and is heavily dependent on the River Murray as a water source. The council seat is at Renmark.

The Murray–Darling Basin Authority (MDBA) is the principal government agency in charge of managing the Murray–Darling Basin in an integrated and sustainable manner. The MDBA is an independent statutory agency that manages, in conjunction with the Basin states, the Murray–Darling basin's water resources in the national interest. The MDBA reports to the Australian Government Minister for the Environment and Water, held since June 2022 by the Hon Tanya Plibersek.

<span class="mw-page-title-main">North–South Pipeline</span> Australian water pipeline near Melbourne

The North–South Pipeline, also known as the Sugarloaf Pipeline, is a water pipeline in Central Victoria, Australia, northeast of Melbourne that is part of Victoria's water system, acting as a link between Melbourne's water grid and the Murray-Goulburn water grid, supplying water via a series of existing and proposed pipelines. The 70-kilometre pipeline was connected to Melbourne in February 2010 to carry water from the Goulburn River to Melbourne's Sugarloaf Reservoir. It is the government's policy that it only be used in times of critical human need: when Melbourne's total water storages are less than 30% full on 30 November of any year. The pipeline can transfer a portion of Lake Eildon's water that is set aside for Melbourne, called the critical water reserve. This was 38,400 megalitres at 2 June 2014, and any changes are based on Goulburn-Murray Water's advice.

Water security in Australia became a major concern in Australia in the late 20th and early 21st century as a result of population growth, recurring severe droughts, effects of climate change on Australia, environmental degradation from reduced environmental flows, competition between competing interests such as grazing, irrigation and urban water supplies, and competition between upstream and downstream users. For example, there is competition for the resources of the Darling River system between Queensland, New South Wales and South Australia. Water reform was first placed on the national agenda at the 1994 Council of Australian Governments (COAG) meeting when a strategic framework was devised. As the knowledge of surface and groundwater systems grew and the awareness of the significance of sustainable water markets increased, further water reform was agreed to at the 2004 COAG meeting, under a national blueprint known as the National Water Initiative (NWI).

<span class="mw-page-title-main">2000s Australian drought</span> Period of low rainfall on the continent

The 2000s drought in Australia, also known as the millennium drought is said by some to be the worst drought recorded since European settlement.

References

  1. "Living with drought". Bureau of Meteorology (Australia). Archived from the original on 18 February 2007. Retrieved 20 February 2007.
  2. 1 2 "Australia's Salinity Problem". National Action Plan for Salinity and Water Quality. Commonwealth of Australia. 2001. Archived from the original on 10 February 2007. Retrieved 23 February 2007.
  3. C. Radcliffe, John (10 February 2022). "Current status of recycled water for agricultural irrigation in Australia, potential opportunities and areas of emerging concern". Science of The Total Environment. 807, Part 2. doi: 10.1016/j.scitotenv.2021.151676 . Retrieved 17 November 2023.
  4. "Burdekin Haughton". SunWater. Retrieved 18 November 2011.
  5. Green, K. D. (1988). "Chapter 3: Irrigation Development". Channels, weirs and barrages. Parkville, Victoria: Australian Academy of Technological Sciences and Engineering. p. 155. ISBN   0-908029-49-7 . Retrieved 21 February 2007.{{cite book}}: |work= ignored (help)
  6. 1 2 Munns, Cec F.; McLay, A.; Sparkes, J.; Logue, W.; Paul, S.; Short, B. (1987). The way we were. Vol. 3 (2nd ed.). South Melbourne, Victoria: Brooks Waterlook Publicaters. p. 266. ISBN   0-85568-507-7.
  7. Westcott, Peter (1979). "Chaffey, William Benjamin (1856 - 1926)". Australian Dictionary of Biography . Australian National University / Melbourne University Press. Retrieved 22 February 2007.
  8. Green, K. D. (1988). "Chapter 3: Irrigation Development". Measuring farm supplies - the Dethridge wheel. Parkville, Victoria: Australian Academy of Technological Sciences and Engineering. p. 157. ISBN   0-908029-49-7 . Retrieved 21 February 2007.{{cite book}}: |work= ignored (help)
  9. Hohnen, Peter (1974). "McCaughey, Sir Samuel (1835 - 1919)". Australian Dictionary of Biography . Melbourne University Press . Retrieved 12 March 2007.
  10. J. M. Powell, Mead, Elwood (1858–1936), Australian Dictionary of Biography, Volume 10, (MUP), 1986
  11. totaltravel.com aerticle on Harvey
  12. 1 2 "Drowned towns". Ergo. State Library of Victoria. Retrieved 18 November 2011.
  13. 1 2 3 4 5 "4610.0 - Water Account, Australia, 2004-05". Australian Bureau of Statistics. 2006. Retrieved 5 March 2007.
  14. "4618.0 - Water Use on Australian Farms, 2006-07". Australian Bureau of Statistics . Australian Government. 27 August 2008. Retrieved 31 March 2009.
  15. 1 2 3 4 "4618.0 - Water Use on Australian Farms, 2008-09". Australian Bureau of Statistics . Australian Government. 19 May 2010. Retrieved 13 May 2010.
  16. 1 2 "4610.0 - Water Account, Australia, 2012-13". Australian Bureau of Statistics. 2006. Retrieved 8 August 2015.
  17. 1 2 3 ABS Media Release November 2006 "Drought drives down water consumption"
  18. 1 2 "Water and Cotton Fact Sheet". Cotton Australia. 13 February 2007. Archived from the original on 28 February 2007. Retrieved 5 March 2007.
  19. "Water and Cotton Fact Sheet". Cotton Australia. 13 February 2007. Archived from the original on 28 February 2007. Retrieved 5 March 2007. From ABS Water Account Australia 2004/05 figures
  20. "The Australian Rice Growing Region". SunRice. Archived from the original on 31 December 2006. Retrieved 28 January 2007.
  21. "Rice Facts". Ricegrowers Association of Australia Inc. Archived from the original on 30 December 2006. Retrieved 28 January 2007.
  22. "SunRice Deniliquin". Ricegrowers Ltd. Archived from the original on 8 October 2006. Retrieved 28 January 2007.
  23. "The table grape industry". Australian Table Grape Association. Retrieved 17 November 2023.
  24. Oag, David (July 2001). Papademetriou, Minas K.; Dent, Frank J. (eds.). "Grape Production in Australia". Grape Production in the Asia-Pacific Region. FAO.
  25. "Water Trading in Australia Current & Prospective Products" (PDF). ACIL Tasman. 2003. Archived from the original (PDF) on 13 November 2006. Retrieved 5 February 2007.
  26. "4618.0 - Water Use on Australian Farms, 2013-14". Australian Bureau of Statistics . Australian Government. 29 April 2015. Retrieved 8 August 2015.
  27. WA Agriculture Bulletin Archived 27 September 2007 at the Wayback Machine
  28. "Wakool Tullakool Sub Surface Drainage Scheme" (PDF). Murray Irrigation Ltd. 2006. Archived from the original (PDF) on 29 August 2007. Retrieved 23 February 2007.
This page is based on this Wikipedia article
Text is available under the CC BY-SA 4.0 license; additional terms may apply.
Images, videos and audio are available under their respective licenses.