coalpetroleum[1].ppt
- 3. Formation of coal Organic matter derived mostly from land plants accumulates in low-energy environment (like a swamp). Oxidative decay uses up lots of oxygen, rendering the sediment pore waters devoid of oxygen (anoxic). Gentle cooking and pressing (lithification) as a result of increasing burial depth remove the pore water and increase carbon content (due to release of volatile components of the organic molecules). Low grade coal (lignite) cooked very little. High grade coal (anthracite) cooked a lot (close to being a metamorphic rock). Lower grade coal tends to contain minerals such as pyrite, which formed under the reducing (low-oxygen) conditions.
- 4. Coal fields in Canada mark regions where swamps bordered shorelines of ancient seas (similar to modern mangrove swamps). Note that the higher coal grades tends to be found closer to mountains where organic-rich sediment has been pressed and cooked more severely. Coal fields
- 5. Uses of Coal Fuel: Canada does not use as much coal as many other countries do for fuel (due to large hydroelectric and nuclear power developments and small population). However, coal is a very important fuel throughout Asia and remains highly significant in the U.S.A, this country having the largest known coal reserves in the world. Coke: Bituminous coal that is cooked (charred) to remove nearly all of the remaining volatiles is transformed into a spongy substance called coke (some of the removed gases, e.g. methane, can themselves be used as fuel). Coke is predominantly burned in blast furnaces to smelt iron from iron ore because it provides the high temperature and gases required for the smelting process (prevents oxidation of the elemental molten iron). It is also used in the production of cement (cooking of limestone and silica).
- 6. Byproducts: A number of by-products from processed coal are also useful. These include organic substances used to make some plastics, medicines, and solvents. Artificial sweeteners such as saccharin and aspartame are also derived from by-products of coal ! Aspartame Aspartame products
- 8. • Oil and natural gas • Oil and natural gas, consisting of various hydrocarbon compounds, are produced in a similar manner though are typically derived from different sources of organic remains. • Derived from the remains of marine plants and animals (mostly plankton). • Oil and natural gas result from the chemical breakdown of these remains in the absence of oxygen, as depth of burial (and therefore temperature) increases. • The oxygen and nitrogen in the original organics are driven off, leaving hydrocarbon compounds (compounds of carbon and hydrogen).
- 9. Oil and gas result from the breakdown of organic molecules (e.g. kerogens) under conditions of increasing temperature, from large complex molecules to smaller, shorter-chain molecules dominated by hydrogen and carbon: a process called “cracking” or “pyrolysis”. This occurs largely through the breaking of C-C bonds. Some gas is produced by decomposition of organic matter by microbes (biogenic gas) Most oil is produced at temperatures between about 60O and 120O C (the oil window). Thermogenic gas is produced as oil is broken down to very small molecules (the smallest being methane) “Oil window” Formation of petroleum (oil and gas) The Oil Window T below: Organics remain largely unaltered. T above: Thermal cracking transforms the petoleum into natural gas.
- 10. • A geologic environment that allows for economically significant amounts of oil and gas to accumulate underground is termed an oil/petroleum trap • Oil and gas is contained in a reservoir. A reservoir must be permeable to oil and gas, and contain sufficient interconnected pore space to accommodate the petroleum. Common examples are poorly lithified sandstones, carbonate reefs, diagenetic carbonates. • The roof of the trap must be made of material that is impermeable to fluids. This is necessary to prevent the upward escape of oil and gas which are much less dense than the surrounding rock. • Common traps include anticline fold traps, fault-bounded traps (structural traps) as well as various stratigraphic traps. Petroleum Traps
- 11. Oil traps occur in many forms In all of these cases: 1. oil and gas accumulates in a restricted area and the top of the permeable reservoir rock unit is sealed by an impermeable caprock Anticline fold trap Fault-bounded trap Stratigraphic trap
- 12. When the cap rock is penetrated by drilling, the oil and natural gas, under pressure, migrate from the pore spaces of the reservoir rock to the drill hole. Note: world’s first commercial oil well was drilled in 1858 at Oil Springs, Ontario (near Sarnia). Before methods were developed to control the upward flow of oil in wells (e.g. blowout preventers), dangerous gushers took place when pressure was suddenly released from oil traps. Recovery of Oil and Gas
- 13. Geographic distribution of oil and gas Major occurrences of oil and gas on continents mark formerly low-lying regions (basins) that were covered by seas (remember that oil and gas is derived from remains of marine organisms). Organic matter in these regions were buried under thick deposits of sediments and gently cooked (e.g. Michigan and Appalachian basins in Ontario).
- 14. Distillation of crude oil Oil is extracted from the ground as crude oil. It is then refined in a distillation tower that is divided into a series of collecting trays at different temperature conditions. The crude oil is boiled to produce vapour. The vapour is allowed to diffuse up the tower to cool and condense at different temperatures (lightest compounds will have lowest boiling temps). The different components of crude oil can therefore be separated. Note: the “naptha” fraction is basically gasoline.
- 15. Fractions that condense in each tray are extracted and used for different purposes. The smallest (lightest; at top) hydrocarbon molecules are used as gases. Intermediate hydrocarbon molecules are used in liquid form. Largest (heaviest; at bottom) hydrocarbon molecules as used as solids (e.g. tar). Fractions obtained from crude oil
- 16. The Versatility of Petroleum The most obvious use for petroleum is as fuel. In Canada, lots of petroleum is used as fuel for heating, transportation, cooking, and electricity generation.
- 17. The Versatility of Petroleum Solvents, used in paints, lacquers, and printing inks, and cleaners Lubricating oils and greases for machinery Petroleum (or paraffin) wax used in candy making, candles, packaging, matches, and polishes …But petroleum-derived organic molecules are also used in an incredible number of other products that include:
- 18. Petroleum jelly (Vaseline), used in medical products and toiletries Asphalt, used to pave roads and airfields and to make roofing materials and floor coverings Plastics and synthetic rubber, used in packaging, casings, fabrics, bubble gum, etc. …and many more !