Relevant bibliographies by topics / Renewable energy sources Australia

Academic literature on the topic 'Renewable energy sources Australia'

Author: Grafiati
Published: 10 December 2022
Last updated: 29 January 2023

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Journal articles on the topic "Renewable energy sources Australia"

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Sokolowski, Maciej M. "Renewable Energy Communities in the Law of the EU, Australia, and New Zealand." European Energy and Environmental Law Review 28, Issue 2 (April 1, 2019): 34–46. http://dx.doi.org/10.54648/eelr2019004.

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The article juxtaposes the regulatory approach to small renewable energy sources and energy communities in the European Union, Australia, and New Zealand, highlighting such matters as the nature, character, and scope of the regulatory model of renewable energy sector. The paper also analyses energy communities in the past, current and drafted European law (as in the "Clean Energy for all Europeans" package) as well as discussing relevant legislation and policies on small renewable energy sources and energy communities in Australia and New Zealand. In this context, this article reviews the possibility of exporting the European model on energy communities outside the EU.
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Arif, Mohammad Taufiqul, Amanullah M. T. Oo, and A. B. M. Shawkat Ali. "Investigation of Energy Storage Systems, Its Advantage and Requirement in Various Locations in Australia." Journal of Renewable Energy 2013 (2013): 1–15. http://dx.doi.org/10.1155/2013/835309.

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Storage minimizes the intermittent nature of renewable sources. Solar and wind are the two fostered source of renewable energy. However, the availability of useful solar radiation and wind speed varies with geographical locations, and also the duration of this energy sources varies with seasonal variation. With the available vast open land and geographical position, Australia has great potential for both solar and wind energies. However, both these sources require energy buffering to support load demand to ensure required power quality. Electricity demand is increasing gradually, and also Australia has target to achieve 20% electricity from renewable sources by 2020. For effective utilization of solar and wind energy potential location of these sources needs to be identified, and effective size of storage needs to be estimated for best utilization according to the load demand. Therefore this paper investigated wind speed and solar radiation data of 210 locations in Australia, identified the potential locations, and estimated required storage in various potential locations to support residential load demand. Advantages of storage were analyzed in terms of loading on distribution transformer and storage support during energy fluctuation from renewable energy. Further analysis showed that storage greatly reduces greenhouse gas emission and reduces overall cost of energy by maximizing the use of solar and wind energies.
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Gill, Roger, and Harry Andrews. "Hydro Tasmania – Renewable Energy Drivers, Action and Plans." Energy & Environment 16, no. 5 (September 2005): 803–13. http://dx.doi.org/10.1260/095830505774478495.

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In Tasmania, the island state of Australia, the generator, Hydro Tasmania, is pushing technical, environmental and business boundaries in its plans to integrate a relatively high proportion (up to 20 percent) of large wind generators into its current complex mix of large and small hydropower plants. Its plans include projects to increase the efficiency of its older hydropower equipment as it prepares to supply much needed peaking capacity to the market in southern Australia via the groundbreaking Basslink undersea cable, which is due for completion in November 2005. Taken as a package these developments are creating a globally significant reference site for renewable energy systems. The paper will describe what is happening, and more importantly what is underpinning the developments, including: the harnessing of Tasmania's world-class wind resource, where recently constructed 1.75 MW wind turbines are achieving capacity factors of over 45 percent – some of the best productivity in the world today; the application of leading environmental science measures to ensure the sustainability of both the new wind farm developments and the transformation of the hydropower system to meet peak capacity demands; the relevance of the existing large hydropower storages that can operate in synergy with the wind resource; the contribution of Australia's renewable energy certificate scheme, which is effectively doubling the value of new renewable energy developments compared with existing generation sources; the application of the latest technology in hydropower turbines, combined with power system expertise from the world's leading manufacturers, to increase the efficiency of older hydropower generators, thereby more effectively harnessing the existing environmental footprint; and the transformation of Hydro Tasmania's business into a significant supplier and trader of premium value peak energy into the sophisticated Australian National Electricity Market.
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Leal, Patrícia H., Antonio Cardoso Marques, and Jose Alberto Fuinhas. "How economic growth in Australia reacts to CO2 emissions, fossil fuels and renewable energy consumption." International Journal of Energy Sector Management 12, no. 4 (November 5, 2018): 696–713. http://dx.doi.org/10.1108/ijesm-01-2018-0020.

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Purpose Australia is one of the ten largest emitters of greenhouse gases but stands out from the others due to its economic growth without recession for 26 consecutive years. This paper aims to focus on the energy-growth nexus and the effects of energy consumption on the environment in Australia. Design/methodology/approach This analysis is performed using annual data from 1965 to 2015 and the autoregressive distributed lag model. Findings The paper finds empirical evidence of a trade-off between economic growth and carbon dioxide (CO2) intensity. The results show that increased gross domestic product (GDP) in Australia increased investment in renewable energy sources (RESs), although the renewable technology is limited and has no impact on reducing CO2 intensity in the long run. In contrast to investment in RES, fossil fuels, coal and oil, are decreased by GDP. However, oil consumption increased renewable energy consumption, and this reflects the pervading effect of the growing economy. Originality/value Overall, this paper contributes to the literature by analysing the behaviour of both energy consumption and the environment on the growing Australian economy. In addition, this paper goes further by studying the impact of economic growth on renewable and non-renewable energy consumption, as well as on CO2 emissions. The study is conducted on a single country for which literature is scarce, using a recent approach and a long time period.
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Lovo, Rena, Eric Gilder, Ora Renagi, and Dapsy Olatona. "Renewable Energy Technologies as “Saving Graces” for Pacific Island Nations Fighting Climate Change." International conference KNOWLEDGE-BASED ORGANIZATION 25, no. 3 (June 1, 2019): 117–25. http://dx.doi.org/10.2478/kbo-2019-0127.

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Abstract In this study, the authors carried out a detailed analysis of the technologies required for successful implementation of a sustainable renewable energy household power supply in Papua New Guinea or PNG (PNG is a Pacific Island nation, North of Australia) to free the country from fossil fuel dependency. The role of renewable energy sources in the recent PNG National Energy Policy covering 2018 to 2050 (unveiled at the 2018 March Energy Summit in Port Moresby by the PNG Minister of Energy) was also analysed. From the outcome of our recently concluded SERI 2018 Renewable Energy conference, we assembled into a single hypothetical ‘energy basket’ all the varied renewable ‘green’ energy sources within PNG (as estimated by our energy research groups). This paper estimates that there is sufficient renewable energy in PNG and advocates that these available green energy sources should be tapped, for they can go a long way in the quest for climate change mitigation. This research paper will articulate that shifting PNG’s and other Pacific Island nations’ energy reliance from fossil fuels and other non-renewable sources to renewable green and environmentally sustainable sources is not only achievable, but feasible within a reasonable time.
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Hasan Chowdhury, Shaheen, and Amanullah Maung Than Oo. "Study on electrical energy and prospective electricity generation from renewable sources in Australia." Renewable and Sustainable Energy Reviews 16, no. 9 (December 2012): 6879–87. http://dx.doi.org/10.1016/j.rser.2012.07.015.

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Bista, Sangita, Philip Jennings, and Martin Anda. "Carbon footprint management of unconventional natural gas development in the export scenario." Renewable Energy and Environmental Sustainability 4 (2019): 3. http://dx.doi.org/10.1051/rees/2018008.

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In Australia, exploitation of shale gas is at an early stage. Western Australia has estimated its technically recoverable gas resources at 235 trillion cubic feet (tcf). It is viewed as an exciting economic prospect and decarbonising option for transition to climate change mitigation. The central focus of this paper is to estimate the climate impacts of Australian shale gas fracking and compare with other energy sources. Electricity generation has been considered as end use of gas in export scenarios to Japan and China. Analysis has been done for resource development periods of 20 and 40 years. Carbon footprints of shale gas range from 604MtCO2e to 543 MtCO2e per annum for China and Japan export cases, respectively, for 20 years field lifetime, if 66 tcf of shale gas is exploited and used. This result is roughly equivalent to 115% of Australia's total national emissions for the year 2014. If all technically recoverable shale gas (235tcf) from the Canning Basin in the Kimberley is exploited and exported to China and Japan over 40 years, the annual emissions are double the total Australian national emissions. The result suggests that shale gas has low carbon intensity compared to coal and oil but solar PV and wind are much cleaner energy options for GHG mitigation. The solar PV and wind electricity would produce 8% and 5% of the shale gas electricity emissions, respectively. Unless accompanied by stringent regulation and compliance on the upstream resource development, stage shale gas cannot be an appropriate energy source for sustainable development as opposed to renewable energy sources.
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Garvie, Leanda C., Stephen H. Roxburgh, and Fabiano A. Ximenes. "Greenhouse Gas Emission Offsets of Forest Residues for Bioenergy in Queensland, Australia." Forests 12, no. 11 (November 15, 2021): 1570. http://dx.doi.org/10.3390/f12111570.

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Harnessing sustainably sourced forest biomass for renewable energy is well-established in some parts of the developed world. Forest-based bioenergy has the potential to offset carbon dioxide emissions from fossil fuels, thereby playing a role in climate change mitigation. Despite having an established commercial forestry industry, with large quantities of residue generated each year, there is limited use for forest biomass for renewable energy in Queensland, and Australia more broadly. The objective of this study was to identify the carbon dioxide mitigation potential of replacing fossil fuels with bioenergy generated from forest harvest residues harnessed from commercial plantations of Pinus species in southeast Queensland. An empirical-based full carbon accounting model (FullCAM) was used to simulate the accumulation of carbon in harvest residues. The results from the FullCAM modelling were further analysed to identify the energy substitution and greenhouse gas (GHG) emissions offsets of three bioenergy scenarios. The results of the analysis suggest that the greatest opportunity to avoid or offset emissions is achieved when combined heat and power using residue feedstocks replaces coal-fired electricity. The results of this study suggest that forest residue bioenergy is a viable alternative to traditional energy sources, offering substantive emission reductions, with the potential to contribute towards renewable energy and emission reduction targets in Queensland. The approach used in this case study will be valuable to other regions exploring bioenergy generation from forest or other biomass residues.
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Wang, Chia-Nan, Thanh-Tuan Dang, Hector Tibo, and Duy-Hung Duong. "Assessing Renewable Energy Production Capabilities Using DEA Window and Fuzzy TOPSIS Model." Symmetry 13, no. 2 (February 18, 2021): 334. http://dx.doi.org/10.3390/sym13020334.

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Climate change and air pollution are among the key drivers of energy transition worldwide. The adoption of renewable resources can act as a peacemaker and give stability regarding the damaging effects of fossil fuels challenging public health as well as the tension made between countries in global prices of oil and gas. Understanding the potential and capabilities to produce renewable energy resources is a crucial pre-requisite for countries to utilize them and to scale up clean and stable sources of electricity generation. This paper presents a hybrid methodology that combines the data envelopment analysis (DEA) Window model, and fuzzy technique for order of preference by similarity to ideal solution (FTOPSIS) in order to evaluate the capabilities of 42 countries in terms of renewable energy production potential. Based on three inputs (population, total energy consumption, and total renewable energy capacity) and two outputs (gross domestic product and total energy production), DEA window analysis chose the list of potential countries, including Norway, United Kingdom, Kuwait, Australia, Netherlands, United Arab Emirates, United States, Japan, Colombia, and Italy. Following that, the FTOPSIS model pointed out the top three countries (United States, Japan, and Australia) that have the greatest capabilities in producing renewable energies based on five main criteria, which are available resources, energy security, technological infrastructure, economic stability, and social acceptance. This paper aims to offer an evaluation method for countries to understand their potential of renewable energy production in designing stimulus packages for a cleaner energy future, thereby accelerating sustainable development.
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Pittock, Barrie. "Co-benefits of large-scale renewables in remote Australia: energy futures and climate change." Rangeland Journal 33, no. 4 (2011): 315. http://dx.doi.org/10.1071/rj11012.

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Desert/remote Australia is blessed with abundant natural energy resources from solar, geothermal and other renewable sources. If these were harnessed and connected appropriately desert/remote Australia could be not only energy self-sufficient but a net exporter. Generation of abundant, clean energy can also attract energy-intensive industries and provide local income and employment. Such co-benefits should be included in any cost-benefit analysis. Regardless of renewable energy’s contribution to reducing climate change, the world is already committed to global warming and associated climate changes. Desert/remote Australia will thus inevitably get warmer, with implications for health, energy demand and other issues, and may be subject to increased extremes such as flooding, longer dry spells, more severe storms and coastal inundation. In addition, the prospect of world demand for oil from conventional sources exceeding supply will likely lead to oil shortages, higher oil prices, and additional incentives to provide alternative energy supplies. The region is heavily reliant on diesel generators and fossil fuel-powered motor vehicles and airplanes for transport for within-region mobility, the importation of goods, the tourism industry and emergency medical services. Without adaptation, climate change and peak oil will make living in desert/remote Australia less attractive, resulting in increased difficulty of attracting and retaining skilled workers, which would constrain development. This paper focuses on the climate and energy-related impacts and potential responses. These are both a challenge and an opportunity. They could provide additional employment and income, thus helping remote communities to participate in the clean energy economy of the future and thus overcome some serious social problems. The paper attempts to review current knowledge and provoke debate on relevant investment strategies, and it teases out the questions in need of further research.
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Dissertations / Theses on the topic "Renewable energy sources Australia"

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Ashby, Scott John. "Remaining off-line : an investigation of Australia's reaction to renewable energy technology development /." Title page, table of contents and abstract only, 1998. http://web4.library.adelaide.edu.au/theses/09ENV/09enva823.pdf.

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Kinrade, Peter. "Sustainable energy in Australia : an analysis of performance and drivers relative to other OECD countries /." Connect to thesis, 2009. http://repository.unimelb.edu.au/10187/3613.

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Blustein, Sholam. "Towards a dignified and sustainable electricity generation sector in Australia : a comparative review of three models." Thesis, Queensland University of Technology, 2012. https://eprints.qut.edu.au/63810/1/Sholam_Blustein_Thesis.pdf.

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Electricity is the cornerstone of modern life. It is essential to economic stability and growth, jobs and improved living standards. Electricity is also the fundamental ingredient for a dignified life; it is the source of such basic human requirements as cooked food, a comfortable living temperature and essential health care. For these reasons, it is unimaginable that today's economies could function without electricity and the modern energy services that it delivers. Somewhat ironically, however, the current approach to electricity generation also contributes to two of the gravest and most persistent problems threatening the livelihood of humans. These problems are anthropogenic climate change and sustained human poverty. To address these challenges, the global electricity sector must reduce its reliance on fossil fuel sources. In this context, the object of this research is twofold. Initially it is to consider the design of the Renewable Energy (Electricity) Act 2000 (Cth) (Renewable Electricity Act), which represents Australia's primary regulatory approach to increase the production of renewable sourced electricity. This analysis is conducted by reference to the regulatory models that exist in Germany and Great Britain. Within this context, this thesis then evaluates whether the Renewable Electricity Act is designed effectively to contribute to a more sustainable and dignified electricity generation sector in Australia. On the basis of the appraisal of the Renewable Electricity Act, this thesis contends that while certain aspects of the regulatory regime have merit, ultimately its design does not represent an effective and coherent regulatory approach to increase the production of renewable sourced electricity. In this regard, this thesis proposes a number of recommendations to reform the existing regime. These recommendations are not intended to provide instantaneous or simple solutions to the current regulatory regime. Instead, the purpose of these recommendations is to establish the legal foundations for an effective regulatory regime that is designed to increase the production of renewable sourced electricity in Australia in order to contribute to a more sustainable and dignified approach to electricity production.
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Romaniuk, O. "Renewable energy sources." Thesis, Видавництво СумДУ, 2009. http://essuir.sumdu.edu.ua/handle/123456789/13666.

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Kondratyuk, O. V. "Renewable energy sources in Ukraine." Thesis, Видавництво СумДУ, 2009. http://essuir.sumdu.edu.ua/handle/123456789/13612.

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Malý, Jan. "Renewable Energy Sources Support Policy." Master's thesis, Vysoká škola ekonomická v Praze, 2009. http://www.nusl.cz/ntk/nusl-11041.

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Renewable energy sources support policy employs a great variety of economic tools in order to promote the use of green energy. Following thesis at first offers an overview and economic insight into the most applied ones. Since the majority of the European Union Member States nowadays prefer so-called feed-in tariffs schemes we proceed in-depth analysis of effectiveness of that instrument in electricity sector in four selected European countries Austria, Czech Republic, Germany and Spain. An effectiveness indicator which compares marginal electricity generation potential with additional realizable potential of particular renewable energy sources technology is used for that analysis. The results clearly show that the best practice of feed-in tariff design is pursued in Germany where the special set of tariff design and adjustment measures is applied.
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Johnson, Darrin B. "Federal renewable-energy research and development funding and innovation /." View online, 2008. http://repository.eiu.edu/theses/docs/32211131423535.pdf.

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Yan, Zuanhong. "Control of fluctuating renewable energy sources : energy quality & energy filters." Thesis, University of Birmingham, 2018. http://etheses.bham.ac.uk//id/eprint/8568/.

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This doctoral study discusses how to control fluctuating renewable energy sources at converter, unit, and system layers to deliver smoothed power output to the grid. This is particularly relevant to renewable power generation since the output power of many kinds of renewable energy sources have huge fluctuations (e.g. solar, wind and wave) that needs to be properly treated for grid integration. In this research, the energy quality is developed to describe the friendliness and compatibility of power flows/waveforms to the grid, by contrast with the well-known concept of power quality which is used to assess the voltage and current waveforms. In Chapter 1 & 2, a background introduction and a literature review of studied subjects are presented, respectively. In Chapter 3, the problem of determining the PI parameters in dq decoupling control of voltage source converter (VSC) is studied based on a state-space model. The problems of the conventional method when there is insufficient interface resistance are addressed. New methods are proposed to overcome these drawbacks. In Chapter 4 & 5, energy quality and the energy filters (EFs) are proposed as tools to assess and manage power fluctuations of renewable energy sources. The proposed EFs are energy storage control systems that could be implemented on a variety of energy storage hardware. EFs behave like low-pass filters to the power flows. Finally, in Chapter 6, as an application example of renewable power plant with energy filter control and smoothed power output, a master-slave wave farm system is proposed. The wave farm system uses enlarged rotor inertia of electric machines as self-energy storage devices.
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Griffin, James. "Improving cost-effectiveness and mitigating risks of renewable energy requirements." Santa Monica, CA : RAND, 2008. http://www.rand.org/pubs/rgs_dissertations/2008/RAND_RGSD236.pdf.

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Thesis (Ph.D.)--RAND Graduate School, 2008.
Title from title screen (viewed on Oct. 24, 2008). "This document was submitted as a dissertation in September 2008 in partial fulfillment of the requirements of the doctoral degree in public policy analysis at the Pardee RAND Graduate School." --T.p. Includes bibliographical references: p. 168-178.
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Mendes, Barlach Leonardo. "Dynamic modelling of variable renewable energy generation sources." Thesis, Massachusetts Institute of Technology, 2017. http://hdl.handle.net/1721.1/112066.

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Thesis: S.M. in Engineering and Management, Massachusetts Institute of Technology, School of Engineering, System Design and Management Program, 2017.
Cataloged from PDF version of thesis.
Includes bibliographical references (page 56).
Renewable energy is one of the most important technologies for decarbonizing the economy and fighting climate change. In recent years, wind energy has become cheaper and more widely adopted. However, the variable nature of wind production creates unique challenges that are not faced by conventional thermal technologies. Several studies to date have showed the decrease in economic value of wind energy as penetration increases due to this variable nature. Plus, they also show that high wind penetration favors intermediate energy sources such as natural gas. I claim however, that few of these studies have considered the dynamic behavior and feedbacks of these systems, including investment delays and learning curves. This thesis uses system dynamics models to simulate the long term changes in the electric grid for Texas. The goal is to test two hypothesis: that the economic value of wind energy decreases as penetration increases, and that variable wind production favors natural gas technologies. It does this by calculating how wind energy changes the shape of the net load duration curve for a given region. This affect changes the profitability of different technologies in unique ways, due to their different fix and variable costs. The conclusions of this thesis are consistent with the literature, with the caveat that they are highly dependent on assumptions regarding the learning curve for energy technologies. The economic value of wind decreases, but this effect can be compensated by lower costs, leading to a continuing adaptation. Faster Wind adoption also reduces the profitably of technologies with high fixed costs such as coal and nuclear, and favors intermediate and peaking sources such as natural gas.
by Leonardo Mendes Barlach.
S.M. in Engineering and Management
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Books on the topic "Renewable energy sources Australia"

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Groom, Susan. Energy options: A booklet produced for the Renewable Energy Advisory Council based on the report, Scenarios for alternative energy in Western Australia. Perth, W.A: The Council, Govt. of Western Australia, 1994.

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Energy, Western Australia Office of the Minister for. Restructure of funding and advisory agencies for alternative energy: A discussion paper prepared by the Government of Western Australia. [Australia: Govt. of Western Australia, 1994.

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Pacific Renewable Energy Forum (2005 Sydney). Proceedings of the Pacific Renewable Energy Forum: 6 July 2005, Sydney Australia. Hobart, Tas: The Green Institute, 2005.

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Fleay, Brian J. Sustainable energy policy for Australia: Submission to the Dept. of Primary Industry and Energy Green Paper 1996. Perth, W.A: Institute for Science and Technology Policy, Murdoch University, 1997.

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Wylie, Lillian. Energy and the environmental challenge: Lessons from the European Union and Australia. Bruxelles: P.I.E. Peter Lang, 2011.

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Asia-Pacific, Renewable Energy Symposium (1995 Sydney N. S. W. ). Asia-Pacific Renewable Energy Symposium '95, Wednesday 26, Thursday 27 & Friday 28 July 1995 ... Sydney, Australia: Applying new & renewable energy technologies to the needs of the region. [Sydney?]: United Nations Economic and Social Commission for Asia and the Pacific, 1995.

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Laughton, M. A. Renewable Energy Sources. London: Taylor & Francis Group Plc, 2004.

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Renewable energy sources. Oxford: Heinemann Library, 2009.

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Laughton, M. A. Renewable energy sources. London: Published on behalf of the Watt Committee on Energy by Elsevier Applied Science, 2003.

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Renewable energy sources. Chicago, Ill: Raintree, 2009.

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Book chapters on the topic "Renewable energy sources Australia"

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Dunlap, Richard A. "Renewable Energy Sources." In Renewable Energy, 39–93. Cham: Springer International Publishing, 2020. http://dx.doi.org/10.1007/978-3-031-02521-1_3.

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Oliveira, João Fernando Gomes de, and Tatiana Costa Guimarães Trindade. "Renewable Energy Sources." In Sustainability Performance Evaluation of Renewable Energy Sources: The Case of Brazil, 19–43. Cham: Springer International Publishing, 2018. http://dx.doi.org/10.1007/978-3-319-77607-1_2.

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Green, David C. "Renewable Energy Sources." In Home Energy Information, 47–51. Cham: Springer International Publishing, 2014. http://dx.doi.org/10.1007/978-3-319-11349-4_7.

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Ketsetzi, Antonia, and Mary Margaret Capraro. "Renewable Energy Sources." In A Companion to Interdisciplinary STEM Project-Based Learning, 145–53. Rotterdam: SensePublishers, 2016. http://dx.doi.org/10.1007/978-94-6300-485-5_17.

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Sharma, Kamal Kant, Akhil Gupta, and Akhil Nigam. "Renewable Energy Sources." In Green Information and Communication Systems for a Sustainable Future, 93–110. First edition. | Boca Raton : CRC Press, 2021. |: CRC Press, 2020. http://dx.doi.org/10.1201/9781003032458-5.

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Kohl, Harald, and Wolfhart Dürrschmidt. "Renewable Energy Sources - a Survey." In Renewable Energy, 4–13. Weinheim, Germany: Wiley-VCH Verlag GmbH & Co. KGaA, 2013. http://dx.doi.org/10.1002/9783527671342.ch1.

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Real, Leandro, Esperanza Sierra, and Alberto Almena. "Renewable Energy Sector." In Alternative Energy Sources and Technologies, 17–30. Cham: Springer International Publishing, 2016. http://dx.doi.org/10.1007/978-3-319-28752-2_2.

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Anderson, Teresa, Alison Doig, Dai Rees, and Smail Khennas. "5. Renewable energy sources." In Rural Energy Services, 67–109. Rugby, Warwickshire, United Kingdom: Practical Action Publishing, 1999. http://dx.doi.org/10.3362/9781780443133.005.

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Misak, Stanislav, and Lukas Prokop. "Renewable Energy Sources—Overview." In Operation Characteristics of Renewable Energy Sources, 1–42. Cham: Springer International Publishing, 2016. http://dx.doi.org/10.1007/978-3-319-43412-4_1.

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Schumacher, Diana. "Renewable Sea Energy Sources." In Energy: Crisis or Opportunity?, 181–202. London: Macmillan Education UK, 1985. http://dx.doi.org/10.1007/978-1-349-17797-4_8.

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Conference papers on the topic "Renewable energy sources Australia"

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Arangarajan, V., Alex Stojcevski, Aman Maung Than Oo, and GM Shafiullah. "Prospect of renewable energy sources and integrating challenges in Victoria, Australia." In 2013 Australasian Universities Power Engineering Conference (AUPEC). IEEE, 2013. http://dx.doi.org/10.1109/aupec.2013.6725370.

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Kwok, Chi Sing, Sathyan Krishnan, Birhane Haile Tesfagergis, and Hung Yao Hsu. "Feasibility Study of using Photovoltaic (PV), Wind and Biogas Renewable Energy System in South Australia Household to Maximize the Energy Production from Renewable Sources." In 2019 Advances in Science and Engineering Technology International Conferences (ASET). IEEE, 2019. http://dx.doi.org/10.1109/icaset.2019.8714316.

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Joseph, Epoupa Mengou, Gambaro Chiara, Alessi Andrea, Terenzi Andrea, Vecchione Michela, Binaschi Marco, Di Salvo Salvatore R, and Norma Anglani. "A Case-Study for the Reduction of CO2 Emissions in an Offshore Platform by the Exploitation of Renewable Energy Sources Through Innovative Technologies Coupled with Energy Storage." In Abu Dhabi International Petroleum Exhibition & Conference. SPE, 2021. http://dx.doi.org/10.2118/207864-ms.

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Abstract Energy storage is entering in the energy distribution supply chain due to the global goal of achieving carbon neutrality in human activities, especially those related to energy production. Renewable energies integrated with energy storage play an important role in this framework [1]. The purpose of the study is to evaluate through simulations the impact of new renewable energy technologies in a microgrid to minimize fossil fuels consumption. The case study considers a hybrid microgrid including: a gas microturbine, organic photovoltaic panels (OPV), a point absorber wave energy converter, a vanadium redox flow battery and a load. The microgrid is placed in an offshore hydrocarbon plant near the northern coast of Australia. Firstly, Australian meteorological data have been studied and three seasons identified (named ST1, ST2 and ST3). Then a correlation has been established between meteorological data and OPVs performances, analyzing data collected on OPVs panels installed. This relationship has been used to assess OPVs potential production at the site of interest. Similar correlation was made between the performances of a wave energy converter placed in the Adriatic Sea and the wave power matrix, to determine a suitable power data reference for the potential production of a wave energy converter to the Australian coast. Finally, the behavior of the microgrid was modeled. Different scenarios have been considered and the best one with optimal meteorological conditions enables lead to drastically decrease of the use of gas micro turbine resulting in lowest CO2 emissions. In fact, the consumption of natural gas has been summarized as follow: Season 1 (ST1): during this season the load is entirely fed by the renewable sources and by the battery, with consequent zeroing of the daily consumption of natural gas. Season 2(ST2): the battery is charged from 09:00am to 07:00pm with the exceeding power from the renewable sources. This configuration involves a daily natural gas consumption of 10.73 Sm3/d, which is equivalent to 987.16 Sm3/ ST2 (accounting for 92 days). Season 3(ST3): the battery is charged from 09:00am to 07:00pm with the exceeding power from the renewable sources. This configuration involves a daily natural gas consumption of 6.58 Sm3/d, which is equivalent to 1006.74 Sm3/ ST3 (accounting for 120 days). The avoided CO2 emissions are 2062 tons/year. This case study showed how the new renewable technologies, such as organic photovoltaics and wave energy converter, coupled with a long duration storage system, can be conveniently applied in sites with limited space for the decarbonization purpose of an offshore platform.
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Islam, M. R., Y. G. Guo, and J. G. Zhu. "H-bridge multilevel voltage source converter for direct grid connection of renewable energy systems." In 2011 IEEE PES Innovative Smart Grid Technologies (ISGT Australia). IEEE, 2011. http://dx.doi.org/10.1109/isgt-asia.2011.6167142.

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Wang, Zhuoyang, Wang Zhang, Liyan Zhang, Guo Chen, Zhaoyang Dong, and Tingwen Huang. "Impact of different penetrations of renewable sources and demand side management on Australian future grid." In 2015 First Workshop on Smart Grid and Renewable Energy (SGRE). IEEE, 2015. http://dx.doi.org/10.1109/sgre.2015.7208723.

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Punanova, Svetlana. "DEVELOPMENT OF THE FUEL AND ENERGY COMPLEX IN CONNECTION WITH THE ADOPTION OF THE DECARBONIZATION LAW (ON THE EXAMPLE OF AUSTRALIA)." In GEOLINKS Conference Proceedings. Saima Consult Ltd, 2021. http://dx.doi.org/10.32008/geolinks2021/b2/v3/33.

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The article, based on the current informational material, provides an overview of the mineral resource complex of Australia and the ways of its development in modern conditions. Modern requirements for the development of the fuel and economic complex of countries are caused by new challenges in connection with the need to follow the Paris Convention on Climate Change and the installation on decarbonization – a significant reduction and then a complete rejection of CO2 emissions from the combustion of hydrocarbons. The work shows that the process of "greening" Australia provides for the creation and implementation of a completely new paradigm for the development of the fuel and energy complex. This is a complete rejection of the extraction and use of coal, an increase in gas production in compliance with environmental requirements, the development and implementation of new technologies, the expansion of gas storage facilities and a network of pipelines, as well as the parallel development and introduction of renewable energy sources.
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"Review of technologies and optimisation methods for integrating renewable energy sources and storage within the Australian National Energy Market." In 20th International Congress on Modelling and Simulation (MODSIM2013). Modelling and Simulation Society of Australia and New Zealand (MSSANZ), Inc., 2013. http://dx.doi.org/10.36334/modsim.2013.g1.cirocco.

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Tapia Olivas, Juan Carlos, René Delgado Rendón, Emilio Hernández Martínez, Felipe Noh Pat, Eric Efrén Villanueva Vega, and María Cristina Castañón Bautista. "Evaluation of Wave Energy in the Pacific Ocean for Baja California State in Mexico." In ASME 2015 International Mechanical Engineering Congress and Exposition. American Society of Mechanical Engineers, 2015. http://dx.doi.org/10.1115/imece2015-52857.

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According to the World Energy Council (WEC) the estimated energy of the wave power in the world is in the range of 8,000 to 80,000 TWh/year to depths of 100 meters or higher and actually the utilization of wave energy resource it is possible because it has been implemented in countries like Australia, Indonesia, Nigeria, United Kingdom, Norway, Portugal and Colombia evaluating different types of marine technologies that take the advantage of the kinetic energy in the ocean waves. Mexico according to the National Institute of Statistics and Information (INEGI) has a land area of 1,972,550 km2 of which has a coastline of 11,150 km having potential for the use of their coasts. Baja California with a land area of 71,445 km2 (3.6% of the country) is located on a peninsula in northwest Mexico and has 720 km of coastline on the Pacific Ocean (6.4% nationally) with a range of depths of 25.6 m to 650 m at a distance of the coastline of 15 km, which makes it suitable to evaluate the use of wave energy at local sites. With the completion of this work will contribute to the characterization of the sites that will present the best technical and economic conditions for its implementation, considering the physical characteristics of the site as well as connection points on the transmission lines operated by the Federal Electricity Commission (CFE). For the preparation of this study was carried out in three stages: a) Site Selection, b) Evaluation of Wave Energy and c) Economic evaluation of sites using RETScreen. Based on the characteristics of the coast of Baja California the results obtained are the following: 1) 18 sites were selected with a sea depth averaged of 50 m, the annual density power was 7.5 kW/m, this represents a potential of 210 MW considering an average length of 2 km in each site, 2) The economic evaluation of this type of project was for a period of 30 years in RETScreen, considers an annual inflation rate of 5% and obtains an investment cost of 9,538 US $/kW for this type of generation. We conclude that this source of energy will reduce dependence on fossil fuels and contribute to the generation of electricity in the state of Baja California diversifying the energetic matrix state by the use of clean and renewable sources, which represents an investment opportunity between the public and private sector.
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"Renewable energy sources and technology." In 2016 10th International Conference on Compatibility, Power Electronics and Power Engineering (CPE-POWERENG). IEEE, 2016. http://dx.doi.org/10.1109/cpe.2016.7544177.

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Kadirova, Seher, and Daniel Kajtsanov. "Renewable energy sources and lighting." In 2018 Seventh Balkan Conference on Lighting (BalkanLight). IEEE, 2018. http://dx.doi.org/10.1109/balkanlight.2018.8546871.

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Reports on the topic "Renewable energy sources Australia"

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Obozov, A. J., and W. V. Loscutoff. Opportunities for renewable energy sources in Central Asia countries. Office of Scientific and Technical Information (OSTI), July 1998. http://dx.doi.org/10.2172/663593.

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Riley, Brad. Scaling up: Renewable energy on Aboriginal lands in north west Australia. Nulungu Research Institute, 2021. http://dx.doi.org/10.32613/nrp/2021.6.

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This paper examines renewable energy developments on Aboriginal lands in North-West Western Australia at three scales. It first examines the literature developing in relation to large scale renewable energy projects and the Native Title Act (1993)Cwlth. It then looks to the history of small community scale standalone systems. Finally, it examines locally adapted approaches to benefit sharing in remote utility owned networks. In doing so this paper foregrounds the importance of Aboriginal agency. It identifies Aboriginal decision making and economic inclusion as being key to policy and project development in the 'scaling up' of a transition to renewable energy resources in the North-West.
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Aminjonov, Farkhod. Renewable Energy Sources: What should be on the Agenda now? The Representative Office of the Institute for War and Peace Reporting in Central Asia, August 2020. http://dx.doi.org/10.46950/202002.

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Barnes, P. R., W. P. Dykas, B. J. Kirby, S. L. Purucker, and J. S. Lawler. The integration of renewable energy sources into electric power transmission systems. Office of Scientific and Technical Information (OSTI), July 1995. http://dx.doi.org/10.2172/108200.

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Barnes, P. R. The Integration of Renewable Energy Sources into Electric Power Distribution Systems. Office of Scientific and Technical Information (OSTI), January 1994. http://dx.doi.org/10.2172/814204.

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Barnes, P. R., J. W. Van Dyke, F. M. Tesche, and H. W. Zaininger. The integration of renewable energy sources into electric power distribution systems. Volume 1: National assessment. Office of Scientific and Technical Information (OSTI), June 1994. http://dx.doi.org/10.2172/10171039.

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Zaininger, H. W. The Integration of Renewable Energy Sources into Electric Power Distribution Systems, Vol. II Utility Case Assessments. Office of Scientific and Technical Information (OSTI), January 1994. http://dx.doi.org/10.2172/814519.

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Zaininger, H. W., P. R. Ellis, and J. C. Schaefer. The integration of renewable energy sources into electric power distribution systems. Volume 2, Utility case assessments. Office of Scientific and Technical Information (OSTI), June 1994. http://dx.doi.org/10.2172/10170818.

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Crumbly, Isaac J., and Haixin Wang. An Analysis of the Use of Energy Audits, Solar Panels, and Wind Turbines to Reduce Energy Consumption from Non Renewable Energy Sources. Fort Belvoir, VA: Defense Technical Information Center, March 2015. http://dx.doi.org/10.21236/ada626067.

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Ayele, Seife, Wei Shen, Frangton Chiyemura, and Jing Gu. Enhancing China–Africa Cooperation in the Renewable Energy Sector. Institute of Development Studies, March 2021. http://dx.doi.org/10.19088/ids.2021.028.

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Access to affordable and sustainable electricity is of fundamental importance to development in much of Africa. But, while access to electricity is improving, contributions from non-hydropower renewable energy sources remain small. At the same time, China – the powerhouse of solar energy technologies – has made limited contribution to harnessing Africa’s renewable energy. Combining insights from recent webinars and research, this Policy Briefing discusses how China–Africa cooperation on renewable energy could lead to improvements in access to and supply of affordable and sustainable energy in Africa. Recommendations for African and Chinese policymakers and businesses include the adoption of transparent, competitive, and locally inclusive energy procurement and use mechanisms.
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