• Energy Research
• 7. Clean energy close

AbstractThe concept of a ‘just transition’ to a low‐carbon economy is firmly embedded in mainstream global discourses about mitigating climate change. Drawing on Karl Polanyi's political economy elaborated inThe Great Transformation, we interrogate the idea of a just transition and place it within its historical context. We address a major contradiction at the core of global energy transition debates: the rapid shift to low‐carbon energy‐systems will require increased extraction of minerals and metals. In doing so, we argue that extractive industries are energy and carbon‐intensive, and will enlarge and intensify social and ecological injustice. Our findings reveal the importance of understanding how the idea of a just transition is used, and by who, and the type of justice that underpins this concept. We demonstrate the need to ground just transition policies and programmes in a notion of justice as fairness.

Straw and other biomasses can cause severe problems when used as fuel in combustion systems. Some of the major problems include high emission of alkalis, HCl, and especially SO2 to the gas phase. T...

Summary Extraheavy-oil (XHO) reservoirs in South America represent some of the largest hydrocarbon accumulations (>500 billion bbl) in the world. Primary production (PP) that uses long horizontal wells is a commercially proved technology for XHO reservoirs. The expected ultimate recovery with primary production is generally less than 12% of original oil in place (OOIP), and thermal enhanced oil recovery (EOR) is critical for increasing recovery to 30–60% OOIP. Economic and environmentally viable thermal development of these reservoirs will require the use of horizontal steam injectors. Our results reveal that continuous steam injection (CSI) with a horizontal injector placed vertically above a horizontal producer (CSI-HIHP) is a very effective method for XHO reservoirs, with high peak-oil rate and significantly high recovery. This study, the first of its kind for an XHO reservoir, outlines an integrated work flow to evaluate the production potential of a large XHO greenfield with PP followed by thermal exploitation. The work flow, based on a probabilistic framework [involving design of experiment (DOE), proxy methods, and Monte Carlo simulations], evaluates reservoir performance for the whole life cycle of the field under a range of uncertainties, and quantifies the impact of key parameters affecting the reservoir performance. XHO reservoirs usually have significantly higher pressures than typical conventional heavy-oil reservoirs, where CSI has been applied commercially. Therefore, pressure in these reservoirs must be reduced before CSI can begin. Cyclic steam stimulation (CSS) after the initial stage of PP can be used to accelerate pressure reduction in the reservoir, while providing additional recovery. Our results demonstrate that geological features such as shale baffles have a significant impact on delaying pressure reduction during PP and CSS. Under a broad range of conditions investigated in this study, PP for 1 year followed by CSS for 4 years has been found to be successful in reducing pressure to the target pressure for CSI. High pressure drop in the horizontal steam injector can cause pressure near the toe region of the injector to be lower than the producer pressure. This results in poor steam injection and poor steam-chest development in that region, thus greatly reducing the efficiency of the thermal-recovery process. We quantify pressure drop in a horizontal steam injector and its impact on the thermal performance and suggest a novel well configuration that uses two injectors for every long producer during CSI. The proposed configuration with a sequential development plan can significantly improve economics of the projects. A novel probabilistic work flow for a full-field (FF) development plan (PP, CSS, and CSI) of XHO reservoirs provides robust production forecast during the entire life cycle. The work flow developed and the insights obtained would be very valuable in preparing effective exploitation plans and optimal facility design, a key economic variable in large projects of developing giant XHO reservoirs.

{"references": ["Retrieved on April 12, 2013 from website http://www.peakbagger.com/range.aspx?rid=432", "Alexander, Christopher, \"Notes on the Synthesis of Form, 1st ed.\", Harvard University Press, 1964, pp. 1-224.", "Borucke, Michael, David Moore, Gemma Cranston, Kyle Gracey, Katsunori Iha, Joy Larson, Elias Lazarus, Juan Carlos Morales, Mathis Wackernagel, Alessandro Galli, 2012, \"Accounting for demand and supply of the biosphere's regenerative capacity: The National Footprint Accounts' underlying methodology and framework\", Ecological Indicators 24 (2013) 518\u2013533, Elsevier Ltd.", "Adams, W.M., \"The Future of Sustainability: Re-thinking Environment and Development in the Twenty-first Century\", 2006, Report of the IUCN Renowned Thinkers Meeting, 29\u201331 January 2006.", "Abdaei, Kaveh, Ahadollag Azami, \"Sustainability Analyses of Passive Cooling Systems in Iranian Traditional Buildings approaching Wind-Catchers\", Recent Advances in Energy, Environment and Development, pp.124-129.", "Afrasiabian, Shaghayegh, Mohammadjavad Mahdavinejad, Negar Badri, \"Nature as a Source of Sustainable Design in Architecture of Original Countries (Case Study: Traditional Architecture of Iran)\", Archi-Cultural Translations through the Silk Road 2nd International Conference, Mukogawa Women's Univ., Nishinomiya, Japan, July 14-16, 2012 Proceedings, pp.257-261.", "Azami.A, Y., \"Climate passive architecture in hot and dry regions of iran, Passive and low energy cooling for the built environment\", Greece: Santorini, 2005, pp. 613-617.", "Fardpour, Tohid, \"Analysis of Iranian Traditional Architecture Through the Lens of Kenneth Frampton's \"Critical Regionalism\"\", American Journal of Engineering and Applied Sciences, 2013, 6 (2): 205-210.", "Ghobadian. Vahid, \"Climate Analysis of the Traditional Iranian Buildings\", 5th ed., Tehran: University of Tehran Press, 2008.\n[10]\tKasmai, Morteza, \"Climate & Architecture\", 4nd ed., 2006, pp. 107-130.\n[11]\tKiani, W. K., \"Cultural heritage organization of Iran\", Tehran, 1995.\n[12]\tPourvahidi, Parastoo, \"Bioclimatic Analysis of Vernacular Iranian Architecture\", Master diss., Eastern Mediterranean University, Gazimagusa, North Cyprus, 2010, 1-161.\n[13]\tPourvahidi, Parastoo, Mesut B. Ozdeniz, \"Bioclimatic analysis of Iranian climate for energy conservation in architecture\", Scientific Research and Essays, 2013, Vol. 8(1), pp. 6-16.\n[14]\tShojaei, S.A.R., Zahra khodayari, \"Sustainable Architecture In Arid Regions of Iran\", 5th Symposium on Advances in Science & Technology, May 12-17, 2011.\n[15]\tUtaberta, N., N. Sharifi, M. Surat, A. I. Che-Ani and N.M. Tawil, \"The Experience of Iranian Architecture in Direction of Urban Passages and Forming of Urban Structures to Increase Climatic Comfort\", World Academy of Science, Engineering and Technology, 2012, Vol. 67, pp. 637-641.\n[16]\tRetrieved on June 2, 2013 from website http://news.discovery.com/earth/global-warming/hottest-spot-on-earth-120416.htm\n[17]\tAttmann, Osman , \"Green architecture: overview\", Green architecture: advanced technologies and materials. definitions and operationalizations of green architecture, McGraw-Hill Professional, AccessEngineering, ICC (International Code Council), 2010, pp. 1-26.\n[18]\tRetrieved on May 28, 2013 from Website http://www.skyscrapercity.com/showthread.php?t=965506\n[19]\tPirnia, Mohammad Karim, Stylistic of Iranian Architecturem, 3rd ed., 1383, pp. 32.\n[20]\tRetrieved on April 18, 2013 from website Website: http://n-a-c.blogfa.com/cat-12.aspx\n[21]\tShokouhian.M, S., \"Enviromental effect of the courtyard in sustainable architecture of Iran\", Tehran: Islamic azad university, 2007.\n[22]\tRetrieved on April 26, 2013 from website http://www.gardenhistorysociety.org/post/agenda/the-gardens-of-persia/\n[23]\tLe Corbusier \"The Modulor: A Harmonious Measure to the Human Scale, Universally Applicable to Architecture and Mechanics\". Basel & Boston: Birkh\u00e4user, (2004) (First published in two volumes in 1954 and 1958.).\n[24]\tRetrieved on May 06, 2013 from website http://ghoolabad.com/index2.asp?id=26"]} Iran Central Plateau encompasses a large proportion of this country. The weather in these flat plains is warm and arid with very little precipitation. Different attempts in architecture have been done to alleviate the weather severity of this area and create a living place compatible with humans’ comfort criteria. Investigations have showed that some of the most successful approaches in traditional architecture of the area has been forgotten or are not being used widely. As sustainability is defined as an appropriate solution for environmental, economical, and social disorders, this research is a try to demonstrate the sustainability in aforementioned architecture and based on these studies, propounds solutions for today architecture in hot arid zones.