Renewable energy in Australia deals with efforts being made in Australia to quantify and expand renewable energy, which includes electricity, transport fuels and thermal energy. Total renewable energy consumption in Australia in 2015 was 346PJ, representing 5.9% of Australia's total energy consumption. This is an increase of 1.6% from 2011-12 levels (265PJ), representing 4.3% of Australia's total energy consumption. Of all renewable energy consumption in 2015 (in order of contribution) biomass (wood, woodwaste and bagasse) represents 53%, hydroelectricity 19.2%, wind 10.7%, solar PV 5.1%, biogas 4.7%, solar hot water 3.8% and biofuels 3.6%. Bioenergy (the sum of all energy derived from plant matter) represented 61.3% (211.9PJ) of Australia's total renewable energy consumption in 2015.
Renewable electricity has undergone substantial growth in Australia in the 21st century. It is estimated that Australia produced 35,007 gigawatt hours (GWh) of renewable electricity (or equivalent) over the year ending December 2015, representing 14.6% of the total production in Australia. By way of comparison, in 2006, approximately 9,500 GWh of electricity came from renewable sources, representing less than 4% of nationally generated electricity.
Of all renewable electrical sources in 2012, hydroelectricity represented 57.8%, wind 26%, bioenergy 8.1%, solar PV 8%, large-scale solar 0.147%, geothermal 0.002% and marine 0.001%; additionally, solar hot water heating was estimated to replace a further 2,422 GWh of electrical generation.
Capacity addition based on renewable energy sources is expected to increase substantially in 2017 with over 49 projects either under construction, constructed or which have secured funding and will go to construction. As of August 2017, it is estimated that Australia generated enough to power 70% of the country's households. It is further estimated that once additional wind and solar projects are complete at the end of the year, that enough energy will be generated to power 90% of the country's homes.
Similar to many other countries, development of renewable electricity in Australia has been encouraged by government energy policy implemented in response to concerns about climate change, energy independence and economic stimulus. A key policy that has been in place since 2001 to encourage large-scale renewable energy development is a mandatory renewable energy target, which in 2010 was increased to 41,000 gigawatt-hours of renewable generation from power stations. This was subsequently reduced to 33,000 gigawatt-hours by the Abbott Government with the agreement of the Labor opposition. Alongside this there is the Small-Scale Renewable Energy Scheme, an uncapped scheme to support rooftop solar power and solar hot water and several State schemes providing feed-in tariffs to encourage photovoltaics. In 2012, these policies were supplemented by a carbon price and a 10 billion-dollar fund to finance renewable energy projects, although these initiatives were later withdrawn by the Federal Government.
It has been suggested that with sufficient public and private sector investment and government policy certainty, Australia could switch entirely to renewable energy within a decade by building additional large-scale solar and wind power developments, upgrading to transmission infrastructure and introduction of appropriate energy efficiency measures.
Maps, Directions, and Place Reviews
Timeline of developments
An unprecedented 39 projects, both solar and wind, with a combined capacity of 3,895 MW are either under construction, constructed or will start construction in 2017 having reached financial closure.
The Australian Federal Government ordered the $10 billion Clean Energy Finance Corporation to refrain from any new investment in wind power projects, with the explanation that the government prefers the corporation to invest in researching new technologies rather than the "mature" wind turbine sector.
Australia could entirely transition to renewable energy within the 2010 decade by building 12 very large scale solar power plants (3500 MW each), which would provide 60% of electricity used, and 6500 7.5 MW wind turbines, which would supply most of the remaining 40%, along with other changes, according to the "Zero Carbon Australia Stationary Energy Plan", for a cost of A$370 billion, about $8/household/week over a decade to create an infrastructure that will last a minimum of 30 to 40 years. Biofuel use is proposed to increase from 2 PJ used in 2010 to 51 PJ/year for modes of transportation not easily electrified, along with some hybrid vehicles. The cost of oil, post peak oil, is increasing, and without converting now to 100% renewable sources the world will pay an additional USD$8 trillion over the next 25 years - and then convert to 100% renewable. Recently an uptake of Third Party ownership models for small to mid-scale solar photovoltaic systems has been seen in Australia mirroring developments in the same direction in the US with over 70% of all new PV systems installed under such models in California, Colorado and Arizona. In Australia the Solar Power Purchase Agreement approach is pursued under the term Solar Sponsoring
Greenpeace released a report in 2008 called "Energy [r]evolution: A Sustainable Energy Australia Outlook", detailing how Australia could produce 40% of its energy through renewable energy by 2020 and completely phase out coal-fired power by 2030 without any job losses. David Spratt and Phillip Sutton argue in their book Climate Code Red that Australia (as part of a concerted global effort) needs to reduce its greenhouse gas emissions down to zero as quickly as possible so that carbon dioxide can be drawn down from the atmosphere and greenhouse gas emissions can be reduced to less than 325 ppm CO2-e, which they argue is the upper "safe climate" level at which we can continue developing infinitely. They outline a plan of action which would accomplish this.
Several reports have discussed the possibility of Australia setting a renewable energy target of 25% by 2020. Combined with some basic energy efficiency measures, such a target could deliver 15,000 MW new renewable power capacity, $33 billion in new investment, 16,600 new jobs, and 69 million tonnes reduction in electricity sector greenhouse gas emissions.
What Are The Types Of Renewable Energy Video
Hydro power
The Snowy Mountains Scheme constructed between 1949 and 1974 consists of sixteen major dams and seven major power stations, and has a total generating capacity of 3,800 MW. The scheme generates on average 4,500 GWh electricity per year. Hydro Tasmania operates thirty power stations and fifty dams, and has a total generating capacity of 2,600 MW. Each year an average of 9,000 GWh of hydro-electricity is generated by the company. In 2007-08 hydro-electricity represented 43% of renewable energy production in Australia. In 2014-15 this had dropped slightly to 39% of renewable energy production.
Wind power
As of July 2017, 15 wind energy projects with a combined generation capacity of around 2,112 MW are either under construction, constructed or will start construction in 2017 having reached financial closure.
By October 2010, around 22.9% of Australia's renewable electricity, and 2% of Australia's total electricity, was sourced from wind power, enough electricity to power more than 700,000 homes. This came from 52 operating wind farms containing a total of 1,052 turbines producing approximately 5,000 GWh of electricity per year. This figure represented approximately a 30% increase in wind power generation each year over the previous decade, or a total increase of more than 1,000% over that time. The total installed capacity as of October 2010 was 1,880 MW (including only projects over 100 kW), with a further 1,043 MW under construction.
Wind power in South Australia is a fast-growing industry as South Australia is well suited for wind farms. Consequently, more wind power is generated in South Australia than any other Australian state or territory. As of October 2010 South Australia had an installed capacity of 907 MW from 435 turbines accounting for close to 20% of that state's electricity needs, considerably ahead of Victoria with 428 MW from 267 turbines, and Western Australia with 202 MW from 142 turbines. By the end of 2011 wind power in South Australia had risen to 26% of the state's electricity generation, edging out coal fired power for the first time. With only 7.2% of Australia's population South Australia had 54% of the nation's installed wind power capacity. Adelaide's $A2.2 billion desalination plant, capable of providing 50% of the city's water needs, is totally powered by renewable energy.
The Waubra Wind Farm near Ballarat, Victoria, completed in 2009, was the largest wind farm in the southern hemisphere, consisting of 128 turbines spread over 173 km2 and rated at 192 MW. However, in terms of generating capacity Lake Bonney Wind Farm near Millicent, South Australia was the largest with 239.5 MW, despite only having 99 turbines. These figures have since been surpassed by the Macarthur Wind Farm at Macarthur, Victoria, which opened in 2013 with a capacity of 420 MW.
Solar photovoltaics
As of June 2017, 31 solar PV projects with a combined generation capacity of around 2,593 MW are either under construction, constructed or will start construction in 2017 having reached financial closure. Two recent projects which illustrate co-operation between industry and government are the solar power station planned for north-western Victoria, and the development of new solar cells. Queensland Solar and Lighting is a major importer of Chinese and European Solar products for the Brisbane region in Queensland, Australia.
Solar photovoltaic (PV) technology generates electricity from sunlight, and it can be used in grid-connected and off-grid applications. They first become mass-produced in 2000, when German environmentalists and Eurosolar succeeded in obtaining the government support for the 100,000 roofs program. According to a report in 2006 the issue for the Australian photovoltaics industry at that time was that there was enormous market potential, built up through a natural competitiveness in Australian research and development, industry investment and government policy support. However, despite this, the industry was not yet self-sustaining and advantages gained to date could be lost. A 2004 market report suggested that a partnership between government and industry was necessary:
"The PV industry cannot continue to actively invest in strategic industry development unless the Australian government is also committed to the journey. The industry ... requires policy and program support to assist it in bridging the gap to mainstream commercial competitiveness."
Mildura Solar concentrator power station
Many projects have demonstrated the feasibility of solar power in Australia and a large new solar power station in Victoria is planned. Solar Systems is to build the world's most advanced photovoltaic (PV) heliostat solar concentrator power station in north-western Victoria. The 154 MW, A$420 million project, will generate 270,000 MWh per year, enough for more than 45,000 homes. It will aid in reducing salinity and create jobs during manufacture, construction and operation. It will also reduce greenhouse gas emissions by approximately 400,000 tonnes per year. Full commissioning is expected in 2013, with the first stage to be completed in 2010. The essential components of the power plant, developed by Solar Systems over the past 16 years, are:
- "An ultra powerful solar module for use in concentrated sunlight".
- "A cooling system to keep solar cells operating at 60 °C to optimise the operation of the PV modules in a concentrated solar beam that can melt steel".
- "Low cost, high performance mirror concentrator systems".
- "A control system to manage the power station to deliver maximum reliability and output".
The commercialisation of this technology has already seen four smaller solar power stations established in central Australia, with support from the Australian Greenhouse Office.
Technology development
SLIVER Cell (TM) photovoltaic technology uses just one tenth of the costly and limited supply of silicon used in conventional solar panels while matching power, performance, and efficiency. Professor Andrew Blakers, Director of the Australian National University Centre for Sustainable Energy Systems, invented the technology with colleague Dr Klaus Weber and developed it with funding from energy supplier Origin Energy and the Australian Research Council. Blakers and Weber won the Australian Institute of Physics' Walsh Medal for their work. Origin Energy is presently developing SLIVER modules for commercialisation at its A$20M pilot plant in Regency Park, South Australia.
Solar Cities
Solar Cities in Australia is a $75 million program which is designed to demonstrate how solar power, smart meters, energy conservation and new approaches to electricity pricing can combine to provide a sustainable energy future in urban locations throughout Australia. It is a partnership approach that involves all levels of Government, the private sector and the local community. Adelaide, Townsville, Blacktown and Alice Springs are the first four solar cities announced in Australia. Consumers will be able to purchase solar photovoltaic panels using discounted loans. The project also plans to help low-income and rental households in the community share in the benefits of the project through other cost-saving initiatives.
Solar thermal energy
Australia has developed world leading solar thermal technologies, but with only very low levels of actual use. Domestic solar water heating is the most common solar thermal technology.
Solar water heating
During the 1950s, Australia's Commonwealth Scientific and Industrial Research Organisation (CSIRO) carried out world leading research into flat plate solar water heaters. A solar water heater manufacturing industry was subsequently established in Australia and a large proportion of the manufactured product was exported. Four of the original companies are still in business and the manufacturing base has now expanded to 24 companies. Despite an excellent solar resource, the penetration of solar water heaters in the Australian domestic market was only about 5% in 2006, with new dwellings accounting for most sales. By 2014, around 14% of Australian households had solar hot water installed It is estimated that by installing a solar hot water system, it could reduce a family's CO2 emissions up to 3 tonnes per year while saving up to 80% of the energy costs for water heating.
While solar water heating saves a significant amount of energy, they are generally omitted from measures of renewable energy production as they do not actually produce electricity. Based on the installed base in Australia as of October 2010, it was calculated that solar hot water units would account for about 7.4% of clean energy production if they were included in the overall figures.
Solar thermal power
CSIRO's National Solar Energy Centre in Newcastle, NSW houses a 500 kW (thermal) and a 1.5 MW (thermal) solar central receiver system, which are used as research and development facilities.
The Australian National University (ANU) has worked on dish concentrator systems since the early 1970s and early work lead to the construction of the White Cliffs solar thermal station. In 1994, the first 'Big Dish' 400 m2 solar concentrator was completed on the ANU campus. In 2005, Wizard Power Pty Ltd was established to commercialise the Big Dish technology to deployment. Wizard Power has built and demonstrated the 500m2 commercial Big Dish design in Canberra and the Whyalla SolarOasis will be the first commercial implementation of the technology, using 300 Wizard Power Big Dish solar thermal concentrators to deliver a 40MWe solar thermal power plant. Construction is expected to commence in mid-late 2013.
Research activities at the University of Sydney and University of New South Wales have spun off into Solar Heat and Power Pty Ltd (now Ausra), which is currently building a major project at Liddell Power station in the Hunter Valley. The CSIRO Division of Energy Technology has opened a major solar energy centre in Newcastle that has a tower system purchased from Solar Heat and Power and a prototype trough concentrator array developed in collaboration with the ANU.
Cloncurry, a town in north-west Queensland, has been chosen as the site for an innovative $31 million (including a $7 million government grant) solar thermal power station. The 10 MW solar thermal power station would deliver about 30 million kilowatt hours of electricity a year, enough to power the whole town. Ergon Energy will develop the project which should be running by early 2010.
In August 2008 Worley Parsons, an Australian engineering firm, announced plans to build world's biggest solar plant in Australia within three years. Backed by nine Australian companies, including miners BHP Billiton and Rio Tinto, they have launched a study into finding possible sites to host the $1 billion plant.
Geothermal energy
In Australia, geothermal energy is a natural resource which is not utilised as a form of energy. However, there are known and potential locations near the centre of the country in which geothermal activity is detectable. Exploratory geothermal wells have been drilled to test for the presence of high temperature geothermal activity and such high levels were detected. As a result, projects will eventuate in the coming years and more exploration is expected at potential locations.
South Australia has been described as "Australia's hot rock haven" and this emissions free and renewable energy form could provide an estimated 6.8% of Australia's base load power needs by 2030. According to an estimate by the Centre for International Economics, Australia has enough geothermal energy to contribute electricity for 450 years.
There are currently 19 companies Australia-wide spending A$654 million in exploration programmes in 141 areas. In South Australia, which is expected to dominate the sector's growth, 12 companies have already applied for 116 areas and can be expected to invest A$524 million (US$435 M) in their projects by the next six years. Ten projects are expected to achieve successful exploration and heat flows, by 2010, with at least three power generation demonstration projects coming on stream by 2012. A geothermal power plant is generating 80 kW of electricity at Birdsville, in southwest Queensland.
Wave power
Several projects for harvesting the power of the ocean are under development:
- Oceanlinx is trialling a wave energy system at Port Kembla.
- Carnegie Corp of Western Australia is refining a method of using energy captured from passing waves, CETO to generate high-pressure sea water. This is piped onshore to drive a turbine and to create desalinated water. A series of large buoys is tethered to piston pumps anchored in waters 15 to 50 metres (49 to 164 ft) deep. The rise and fall of passing waves drives the pumps, generating water pressures of up to 1,000 pounds per square inch (psi). The company is looking to have a 50 MW demonstration project finished within the next four years.
- BioPower Systems is developing its bioWAVE system anchored to the seabed that would generate electricity through the movement of buoyant blades as waves pass, in a swaying motion similar to the way sea plants, such as kelp, move. It expects to complete pilot wave and tidal projects off northern Tasmania this year.
Bio-energy
Biomass
Biomass can be used directly for electricity generation, for example by burning sugar cane waste (bagasse) as a fuel for thermal power generation in sugar mills. It can also be used to produce steam for industrial uses, cooking and heating. It can also be converted into a liquid or gaseous biofuel. In 2015 Bagasse accounted for 26.1% (90.2PJ) of Australia's renewable energy consumption, while wood and woodwaste for another 26.9% (92.9PJ). Biomass for energy production was the subject of a federal government report in 2004.
Biofuels
Biofuels produced from food crops have become controversial as food prices increased significantly in mid-2008, leading to increased concerns about food vs fuel. Ethanol fuel in Australia can be produced from sugarcane or grains and there are currently three commercial producers of fuel ethanol in Australia, all on the east coast. Legislation imposes a 10% cap on the concentration of fuel ethanol blends. Blends of 90% unleaded petrol and 10% fuel ethanol are commonly referred to as E10, which is mainly available through service stations operating under the BP, Caltex, Shell, and United brands. In partnership with the Queensland Government, the Canegrowers organisation launched a regional billboard campaign in March 2007 to promote the renewable fuels industry. Over 100 million litres of the new BP Unleaded with renewable ethanol has now been sold to Queensland motorists. Biodiesel produced from oilseed crops or recycled cooking oil may be a better prospect than ethanol, given the nation's heavy reliance on road transport, and the growing popularity of fuel-efficient diesel cars. Australian cities are some of the most car-dependent cities in the world, and legislations involving vehicle pollution within the country are considered relatively lax.
Major renewable energy companies
BP Solar
BP has been involved in solar power since 1973 and its subsidiary, BP Solar, is now one of the world's largest solar power companies with production facilities in the United States, Spain, India and Australia. BP Solar is involved in the commercialisation of a long life deep cycle lead acid battery, jointly developed by the CSIRO and Battery Energy, which is ideally suited to the storage of electricity for renewable remote area power systems (RAPS).
Edwards
Edwards first began manufacturing water heaters in Australia in 1963. Edwards is now an international organisation which is a leader in producing hot water systems for both domestic and commercial purposes using solar technology. Edwards exports to Asia, the Pacific, the Americas, Europe, Africa and the Middle East.
Eurosolar
Eurosolar was first formed in 1993, with an aim of providing photovoltaic systems to the masses. It focuses on Solar Power in multiple Australian capitals. They continue to install panels all around Australia.
Origin Energy
Origin Energy is active in the renewable energy arena, and has spent a number of years developing several wind farms in South Australia, a solar cell business using technology invented by a team led by Professor Andrew Blakers at the Australian National University, and geothermal power via a minority shareholding stake in Geodynamics.
Pacific Hydro
Pacific Hydro is an Australian company that specialises in electricity generation using renewable energy. Its focus is on hydroelectricity and wind power. Power stations owned by Pacific Hydro include wind farms: Codrington Wind Farm, Challicum Hills Wind Farm, Portland Wind Project and Hydro power: Eildon Pondage Power Station, Ord River Hydro Power Station and The Drop Hydro.
Snowy Hydro Limited
Snowy Hydro Limited, previously known as the Snowy Mountains Hydro-Electric Authority, manages the Snowy Mountains Scheme which generates on average around 4500 gigawatt hours of renewable energy each year, which represented around 74% of all renewable energy in the National Electricity Market in 2005. The scheme also diverts water for irrigation from the Snowy River Catchment west to the Murray and Murrumbidgee River systems.
Solahart
Solahart manufactured its first solar water heater in 1953, and products currently manufactured by Solahart include thermosiphon and split system solar and heat pump water heaters. These are marketed in 90 countries around the world and overseas sales represent 40% of total business. Solahart has a market share of 50% in Australia.
Solar Systems
Solar Systems was a leader in high concentration solar photovoltaic applications, and the company built a photovoltaic Mildura Solar concentrator power station, Australia. This project will use innovative concentrator dish technology to power 45,000 homes, providing 270,000 MWh/year for A$420 million. Solar Systems has already completed construction of three concentrator dish power stations in the Northern Territory, at Hermannsburg, Yuendumu, and Lajamanu, which together generate 1,555 MWh/year (260 homes, going by the energy/home ratio above). This represents a saving of 420,000 litres of diesel fuel and 1550 tonnes of greenhouse gas emissions per year. The total cost of the solar power station was "A$7M, offset by a grant from the Australian and Northern Territory Governments under their Renewable Remote Power Generation Program". The price of diesel in remote areas is high due to added transportation costs: in 2017, retail diesel prices in remote areas of the Northern Territory averaged $1.90 per litre. The 420,000 litres of diesel per year saved by these power stations in the first decade of operation would thus have cost approximately $8,000,000.
Wind Prospect
Wind Prospect developed the 46 MW Canunda Wind Farm in South Australia, which was commissioned in March 2005. A second South Australian wind farm, Mount Millar Wind Farm, was commissioned in January 2006 and this provides a further 70 MW of generation. More recently, a third wind farm has reached financial close for Wind Prospect in South Australia. This is the 95 MW Hallett Wind Farm which is expected to be fully commissioned late in 2008.
Government policy
There are a number of government policies in place in Australia that influence the development of renewable energy.
Mandatory Renewable Energy Target (MRET) schemes
A key policy encouraging the development of renewable energy in Australia includes Mandatory Renewable Energy Target (MRET) schemes at both Commonwealth and State levels. In 2001, the Howard Government introduced an MRET of 9,500 GWh of new renewable energy generation by 2010.
An Expanded Renewable Energy Target was passed with broad support by the Australian Parliament on 20 August 2009, to ensure that renewable energy obtains a 20% share of electricity supply in Australia by 2020. To ensure this the Federal Government committed to increasing the MRET from 9,500 gigawatt-hours to 45,000 gigawatt-hours by 2020. The scheme was scheduled to last until 2030. This target has since been revised with the Gillard Government introducing in January 2011 an expanded target of 45,000 GWh of additional renewable energy between 2001 and 2020.
The MRET was split in 2012 into a small scale renewable energy scheme (SRES) and large scale renewable energy target (LRET) components to ensure that adequate incentive exists for large scale grid connected renewable energy. A number of states have also implemented their own renewable energy targets independent of the Commonwealth. For example, the Victorian Renewable Energy Target Scheme (VRET) mandated an additional 5% of Victoria's "load for renewable generation", although this has since been replaced by the new Australian Government LRET and SRES targets. South Australia achieved its target of 20% of renewable supply by 2014 three years ahead of schedule (i.e. in 2011) and has subsequently established a new target of 33% to be achieved by 2020.
Renewable Energy Certificates Registry
The Renewable Energy Certificates Registry (REC-registry) is an internet based registry system that is required by the Australian Renewable Energy (Electricity) Act 2000 (the Act). The REC-registry is dedicated to: maintaining various registers (as set in the Act); and facilitating the creation, registration, transfer and surrender of renewable energy certificates (RECs).
Carbon pricing
In 2012, the Gillard government implemented a carbon price of $23 per tonne to be paid by 300 liable entities representing the highest business emitters in Australia. The carbon price will increase to $25.40 per tonne by 2014-15, and then will be set by the market from 1 July 2015 onwards. It is expected that in addition to encouraging efficient use of electricity, pricing carbon will encourage investment in cleaner renewable energy sources such as solar and wind power. Treasury modelling has projected that with a carbon price, energy from the renewables sector is likely to reach 40 percent of supply by 2050. Analysis of the first 6 months of operation of the carbon tax have shown that there has been a drop in carbon emissions by the electricity sector. It has been observed that there has been a change in the mix of energy over this period, with less electricity being sourced from coal and more being produced by renewables such as hydro and wind power. The government at the time presented this analysis as an indicator that their policies to promote cleaner energy are working. The carbon pricing legislation was repealed by the Tony Abbott-led Australian Government on 17 July 2014. Since then, carbon emissions from the electricity sector have increased.
Clean Energy Finance Corporation
The Australian Government has announced the creation of the new 10 billion dollar Clean Energy Finance Corporation which will commence business in July 2013. The goal of this intervention is to overcome barriers to the mobilisation of capital by the renewable energy sector. It will make available two billion dollars a year for five years for the financing of renewable energy, energy efficiency and low emissions technologies projects in the latter stages of development. The government has indicated that the fund is expected to be financially self-sufficient producing a positive return on investment comparable to the long term bond rate.
Feed-in tariffs
Feed-in tariffs have been enacted on a state by state basis in Australia to encourage investment in renewable energy by providing above commercial rates for electricity generated from sources such as rooftop photovoltaic panels or wind turbines. The schemes in place focus on residential scale infrastructure by having limits that effectively exclude larger scale developments such as wind farms. Feed-in tariffs schemes in Australia started at a premium, but have mechanisms by which the price paid for electricity decreases over time to be equivalent or below the commercial rate. All the schemes now in place in Australia are "net" schemes whereby the householder is only paid for surplus electricity over and above what is actually used. In the past, New South Wales and the Australian Capital Territory enacted "gross" schemes whereby householders were entitled to be paid for 100% of renewable electricity generated on the premises, however these programs have now expired. In 2008 the Council of Australian Governments (COAG) agreed to harmonise the various state schemes and developed a set of national principles to apply to new schemes. Leader of the Australian Greens, Christine Milne, has advocated a uniform national "gross" feed-in tariff scheme, however this proposal has not been enacted.
Subsidies to fossil fuel industry
There is dispute about the level of subsidies paid to the fossil fuel industry in Australia. The Australian Conservation Foundation (ACF) argues that according to the definitions of the Organisation for Economic Co-operation and Development (OECD), fossil fuel production and use is subsidised in Australia by means of direct payments, favourable tax treatment, and other actions. It is suggested these measures act as impediments to investment in renewable energy resources. Analysis by the ACF indicates that these provisions add up to a total annual subsidy of A$7.7 billion, with the most significant component being the Fuel Tax Credits program that rebates diesel fuel excise to many business users. This analysis is disputed by the Institute of Public Affairs (IPA) who argue that the ACF's definition of a subsidy differs from that of the OECD and that the fuel tax rebate schemes are in place to ensure that all producers are treated equally from a tax point of view. However, the IPA acknowledges that regardless of perceived issues with the ACF analysis, some level of fossil fuel subsidy is likely in existence.
Ratification of the Kyoto Protocol
Australia ratified the Kyoto Protocol in December 2007 under the then newly elected Prime Minister Kevin Rudd. Evidence suggests Australia will meet its targets required under this protocol. Australia had not ratified the Kyoto Protocol until then, due to concerns over a loss of competitiveness with the US, which also rejects the treaty.
Public opinion and action
Survey results suggest that there is considerable public support for the use of renewable energy and energy efficiency in Australia. In one recent survey, 74% of respondents favoured a "greenhouse strategy based mainly on energy efficiency and renewable energy, and 19% favoured an "approach that focuses mainly on nuclear power and clean coal technologies." The Australian results from the 1st Annual World Environment Review, based on a survey of 1,007 people in 2007, found that:
- 88% of Australians think that the Government should do more to increase the use of solar power. 78% say the government should do more to boost wind power, 58% hydro power, 50% tidal power, and 38% geothermal power, while only 25% think that the Government should do more to increase use of nuclear power.
- 84% of Australians think that the Government should make it easier for people to buy renewable electricity.
- 89% think that all electricity should contain a minimum 25% of power generated from renewable energy sources. Only 3% disagree.
- 82% think that the Government should make it easier for people to buy solar panels.
- 80% think that the Government should make it easier for people to buy energy efficient products, such as energy-saving light globes, water-saving shower heads and insulation etc.
- 85% think that the Government should raise national fuel efficiency standards for cars and light trucks.
- 87% think that the Government should do more to increase the number of cars that don't use petrol.
There is a considerable movement known as The Transition Decade to transition Australia's entire energy system to renewable by 2020. Voluntary uptake of GreenPower, a Government program initiated in 1997 whereby people can pay extra for electricity that is generated from renewable sources, increased from 132,300 customers in 2005 to 904,716 customers in 2009.
Academic literature
Australia has a very high potential for renewable energy. Therefore, the transition to a renewable energy system is gaining momentum in the peer-reviewed scientific literature. Among them several studies have examined the feasibility of a transition to a 100% renewable electricity systems, which was found both practicable as well as economically and environmentally beneficial to combat global warming.
Source of the article : Wikipedia
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