Heavy crude oil
Heavy crude oil (or extra heavy crude oil) is highly-viscous oil that cannot easily flow to production wells under normal reservoir conditions.
It is referred to as "heavy" because its density or specific gravity is higher than that of light crude oil. Heavy crude oil has been defined as any liquid petroleum with an API gravity less than 20°. Physical properties that differ between heavy crude oils and lighter grades include higher viscosity and specific gravity, as well as heavier molecular composition. In 2010, the World Energy Council defined extra heavy oil as crude oil having a gravity of less than 10° and a reservoir viscosity of no more than 10,000 centipoises. When reservoir viscosity measurements are not available, extra-heavy oil is considered by the WEC to have a lower limit of 4° °API. In other words, oil with a density greater than 1000 kg/m3 or, equivalently, and a specific gravity greater than 1 and a reservoir viscosity of no more than 10,000 centipoises. Heavy oils and asphalt are dense nonaqueous phase liquids (DNAPLs). They have a low solubility and a viscosity lower than, and density higher than, water. Large spills of DNAPL will quickly penetrate the full depth of the aquifer and accumulate on its bottom.
Heavy crude oil is closely related to natural bitumen from oil sands. Petroleum geologists categorize bitumen from oil sands as ‘extra-heavy oil’ due to its density of less than 10° °API. Bitumen is the heaviest, thickest form of petroleum. According to the U.S. Geological Survey, bitumen is further distinguished as extra-heavy oil with a higher viscosity (i.e., resistance to flow): “Natural bitumen, also called tar sands or oil sands, shares the attributes of heavy oil but is yet more dense and viscous. Natural bitumen is oil having a viscosity greater than 10,000 cP.” “Natural bitumen (often called tar sands or oil sands) and heavy oil differ from light oils by their high viscosity (resistance to flow) at reservoir temperatures, high density (low API gravity), and significant contents of nitrogen, oxygen, and sulfur compounds and heavy-metal contaminants. They resemble the residuum from the refining of light oil. Most heavy oil is found at the margins of geologic basins and is thought to be the residue of formerly light oil that has lost its light-molecular-weight components through degradation by bacteria, water-washing, and evaporation. Conventional heavy oil and bitumens differ in the degree by which they have been degraded from the original crude oil by bacteria and erosion.(Meyer, 2003 & 1) Often, bitumen is more viscous than cold molasses and does not flow at ambient conditions.
According to World Resources Institute, concentrations of remarkable quantities of heavy oil and oil sands are found in Canada and Venezuela. The U.S. Energy Information Administration (EIA) reported in 2001 that the largest reserves of heavy crude oil in the world were located north of the Orinoco river 270-mile long by 40-mile wide Orinoco Belt in eastern Venezuela. At that time Venezuela began authorizing "joint ventures to upgrade the extra-heavy crude resources."  Petroleos de Venezuela, S.A. (PDVSA) at that time estimated that there were 270 billion barrels of recoverable reserves in the area, the same amount as the conventional oil reserves of Saudi Arabia. The Orinoco Belt in Venezuela is sometimes described as oil sands, but these deposits are non-bituminous, falling instead into the category of heavy or extra-heavy oil due to their lower viscosity. Natural bitumen and extra-heavy oil differ in the degree by which they have been degraded from the original conventional oils by bacteria. Thirty or more countries are known to have reserves.
Production, transportation, and refining of heavy crude oil present special challenges compared to light crude oil. Generally, a diluent is added at regular distances in a pipeline carrying heavy crude to facilitate its flow. Dilbit (diluted bitumen) is a means of transporting highly viscous hydrocarbon. Per the Alberta Oil Sands Bitumen Valuation Methodology, "Dilbit Blends" means "Blends made from heavy crudes and/or bitumens and a diluent usually condensate, for the purpose of meeting pipeline viscosity and density specifications, where the density of the diluent included in the blend is less than 800 kg/m3."
Heavy crude oils provide an interesting situation for the economics of petroleum development. The resources of heavy oil in the world are more than twice those of conventional light crude oil. In October 2009, the United States Geological Survey updated the Orinoco deposits (Venezuela) recoverable value to 513 billion barrels (8.16×1010 m3), making this area one of the world's largest recoverable oil deposits. However, recovery rates for heavy oil are often limited from 5-30% of oil in place. The chemical makeup is often the defining variable in recovery rates. New technology utilized for the recovery of heavy oil is constantly increasing recovery rates.
On one hand, due to increased refining costs and high sulfur content for some sources, heavy crudes are often priced at a discount to lighter ones. The increased viscosity and density also makes production more difficult (see reservoir engineering). On the other hand, large quantities of heavy crudes have been discovered in the Americas, including Canada, Venezuela and California. The relatively shallow depth of heavy oil fields (often less than 3000 feet) can contribute to lower production costs; however, these are offset by the difficulties of production and transport that render conventional production methods ineffective. Specialized techniques are being developed for exploration and production of heavy oil.
Production of heavy oil is becoming more common in many countries, with 2008 production led by Canada and Venezuela. Methods for extraction include Cold heavy oil production with sand, steam assisted gravity drainage, steam injection, vapor extraction, Toe-to-Heel Air Injection (THAI), and open-pit mining for extremely sandy and oil-rich deposits.
With current production and transportation methods, heavy crudes have a more severe environmental impact than light ones. With more difficult production comes the employment of a variety of enhanced oil recovery techniques, including steam flooding and tighter well spacing, often as close as one well per acre. Heavy crude oils also carry contaminants. For example, Orinoco extra heavy oil contains 4.5% sulfur as well as vanadium and nickel. However, because crude oil is refined before use, generating specific alkanes via cracking and fractional distillation, this comparison is not valid in a practical sense. Heavy crude refining techniques may require more energy input though, so its environmental impact is presently more significant than that of lighter crude if the intended final products are light hydrocarbons (gasoline motor fuels). On the other hand, heavy crude is a better source for road asphalt mixes than light crude.
With present technology, the extraction and refining of heavy oils and oil sands generates as much as three times the total CO2 emissions compared to conventional oil, primarily driven by the extra energy consumption of the extraction process (which may include burning natural gas to heat and pressurize the reservoir to stimulate flow). Current research into better production methods seek to reduce this environmental impact.
In a 2009 report, the National Toxics Network, citing data provided by the Carbon Dioxide Information Analysis Center of the government of the United States and the Canadian Association of Petroleum Producers (CAPP), stated that emissions of CO2 per unit of energy produced were ~84% of those for coal (0.078/0.093) - higher than CO2 emissions of conventional oil.
Environmental Research Web has reported that "because of the energy needed for extraction and processing, petroleum from Canadian oil tar sands has higher life cycle emission" compared with conventional fossil fuels; "up to 25% more."
Most geologists agree that crude becomes ‘heavy’ as a result of biodegradation, in which lighter ends are preferentially consumed by bacterial activity in the reservoir, leaving heavier hydrocarbons behind. This hypothesis leans heavily on the techniques of petroleum geochemistry. Poor geologic reservoir sealing exposes the hydrocarbon to surface contaminants, including organic life (such as bacteria) and contributes to this process.
Heavy oils can be found in shallow, young reservoirs, with rocks from the Pleistocene, Pliocene, and Miocene (younger than 25 million years). In some cases, it can also be found in older Cretaceous, Mississippian, and Devonian reservoirs. These reservoirs tend to be poorly sealed, resulting in heavy oil and oil-sands.
Heavy oil is asphaltic and contains asphaltenes and resins. It is "heavy" (dense and viscous) due to the high ratio of aromatics and naphthenes to linear alkanes and high amounts of NSOs (nitrogen, sulfur, oxygen and heavy metals). Heavy oil has a higher percentage of compounds with over 60 carbon atoms and hence a high boiling point and molecular weight. For example, the viscosity of Venezuela's Orinoco extra-heavy crude oil lies in the range 1000–5000 cP (1–5 Pa·s), while Canadian extra-heavy crude has a viscosity in the range 5000–10,000 cP (5–10 Pa·s), about the same as molasses, and higher (up to 100,000 cP or 100 Pa·s for the most viscous commercially exploitable deposits). A definition from the Chevron Phillips Chemical company is as follows:
The "heaviness" of heavy oil is primarily the result of a relatively high proportion of a mixed bag of complex, high molecular weight, non-paraffinic compounds and a low proportion of volatile, low molecular weight compounds. Heavy oils typically contain very little paraffin and may or may not contain high levels of asphaltenes.
Heavy crude oil is generally categorized in two ways:
- Those that have over 1% sulfur (high sulfur crude oils), with aromatics and asphaltenes. These are mostly found in North America (Canada (Alberta, Saskatchewan), United States (California), Mexico), South America (Venezuela, Colombia and Ecuador) and the Middle East (Kuwait, Saudi Arabia).
- Those that have less than 1% sulfur (low sulfur crude oils), with aromatics, naphthenes and resins, and these are mostly found in Western Africa (Chad), Central Africa (Angola) and East Africa (Madagascar).
- A. Mai; J. Bryan; N. Goodarzi; A. Kantas (2006). Insights Into Non-Thermal Recovery of Heavy Oil. World Heavy Oil Conference (WHOC). Calgary, Alberta.
- Dusseault, M.B. (12–14 June 2001). Comparing Venezuelan and Canadian Heavy Oil and Tar Sands (PDF). Calgary, Canada: Canadian International Petroleum Conference. Retrieved 5 May 2008.
- Attanasi, Emil D.; Meyer, Richard F. (2010). "Natural Bitumen and Extra-Heavy Oil" (PDF). Survey of energy resources (22 ed.). World Energy Council. pp. 123–140. ISBN 978-0-946121-26-7. Archived from the original (PDF) on 2013-08-24.
- WEC (2007). Survey of Energy Resources 2007: Natural Bitumen - Definitions. World Energy Council. Archived from the original on 2013-10-31.
- Rodriguez H. A., Vaca P., Gonzalez O., and De Mirabal M. C., "Integrated study of a heavy oil reservoir in the Orinoco Belt : A field case simulation" 
- Manuel Ramâon Llamas; Emilio Custodio, eds. (2003). Intensive Use of Groundwater: Challenges and Opportunities. CRC Press. p. 478.page 118
- Jaroslav Vrba; Brian Adams, eds. (2008). Groundwater Early Warning Monitoring Strategy A Methodological Guide (PDF) (Report).
- Meyer, Richard; Atanasi, Emil (August 2003). Heavy Oil and Natural Bitumen--Strategic Petroleum Resources - "Definitions." (Report). U.S. Geological Survey Fact Sheet 70-03. Retrieved 31 July 2013.
- G.R. Gray; R. Luhning. Bitumen. Canadian Encyclopedia.
- Heavy Oil and Tar Sands (Report). Washington, DC: World Resources Institute.
- Venezuela Offers Full Market Value to Encourage Foreign Investment in Oil (Report). Washington, DC: Energy Information Administration. 2001. Archived from the original on 2008-05-05.
- Talwani, M. The Orinoco heavy oil belt in Venezuela (Or heavy oil to the rescue? (Report).
- Dusseault, M. B. (12–14 June 2001). "Comparing Venezuelan and Canadian heavy oil and tar sands". Proceedings of Petroleum Society's Canadian International Conference. 2001-061: 20p.
- Alberta Oil Sands Bitumen Valuation Methodology (PDF), 2008-9995, Calgary, Alberta: Canadian Association of Petroleum Producers, Dec 2008
- Bret Schulte (4 April 2003). "Oil Spill Spotlights Keystone XL Issue: Is Canadian Crude Worse?". Fayetteville, Arkansas: National Geographic News.
- Christopher J. Schenk, Troy A. Cook, Ronald R. Charpentier, Richard M. Pollastro, Timothy R. Klett, Marilyn E. Tennyson, Mark A. Kirschbaum, Michael E. Brownfield, and Janet K. Pitman. (11 January 2010). "An Estimate of Recoverable Heavy Oil Resources of the Orinoco Oil Belt, Venezuela" (PDF). USGS. Retrieved 23 January 2010.CS1 maint: Uses authors parameter (link)
- "Energy Internet" (PDF). www.energy.alberta.ca.
- The Leading Edge, Special Section - Heavy Oil. Vol. 27, No. 8. September, 2008. Society of Exploration Geophysicists.
(Report). World Energy Council (WEC) https://web.archive.org/web/20070402100135/http://www.worldenergy.org/wec-geis/publications/default/tech_papers/17th_congress/3_1_04.asp. Archived from the original on 2007-04-02. Missing or empty
- J.R. Century. Tar Sands: Key geologic risks and opportunities. The Leading Edge, Vol. 27, No. 9, Pg. 1202-1204. September 2008.
- "The Heavy Oil Power Deal. A Dark Cloud over East Timor's Bright Future" (PDF).
- "Blog Archives – Physics World". Physics World.
- "What causes heavy oil if they don't have asphaltene or paraffin problems?" - Chevron Phillips Chemical