1 / 49

Energy Use and Alternative Energy Sources

Energy Use and Alternative Energy Sources. Size of each trophic level is proportional to the energy acquired from the level below. Only about 10% of energy is transferred between trophic levels. Very inefficient!. What is Carbon?. Basis of all life forms (as we know them)

Download Presentation

Energy Use and Alternative Energy Sources

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript


  1. Energy Use and Alternative Energy Sources

  2. Size of each trophic level is proportional to the energy acquired from the level below. Only about 10% of energy is transferred between trophic levels. Very inefficient!

  3. What is Carbon? • Basis of all life forms (as we know them) • Can derive ‘energy’ from carbon compounds to ‘do work’ • Ex: energy (carbon) from food • Ex: energy from fossil fuels (‘hydrocarbons’ CH) • Law: Energy is never created nor destroyed, it can only be converted to different forms • Ex: when we burn fossil fuels, we break the chemical bonds in hydrocarbons (CH) and release carbon in different forms that are greenhouse gases (CO2, CH4)

  4. Central Questions • What are the patterns of energy use around the globe and in the US? • What is the connection between energy use and carbon dioxide (CO2)? • What are the different sources of energy? • What are the pros and cons of each energy source? • Which sources are renewable and which are non-renewable?

  5. Energy Demand • Industrialized nations rely on vast quantities of energy to power their economies and produce goods and services. • As populations increase and citizens demand better standards of living, global energy use will continue to rise • Developing nations account for a growing share of total world demand

  6. Increasing Demand for Energy This projection assumes that current laws and policies remain unchanged. Many factors (economic growth rates, oil prices, and intensity of energy use) could alter these projections.

  7. Global Energy Use • Fossil fuels (coal, oil, natural gas) • Fossil fuels account for 80% global energy use • Fossil fuels account for 86% US energy use

  8. Energy Consumption in the United States

  9. What human activity uses the most energy? • Industrial activity • Residential and commercial consumption (heating, hot water heating, appliances) • Generation of Electric Power • Transportation

  10. US primary energy source is oil (petroleum)Consumption, Production, and Imports of Petroleum Products

  11. Oil Production Predictions Oil production might peak around 2010.

  12. Our fossil fuel culture • Today most of the world's energy is derived from fossil fuels, which are non-renewable resources (available only in limited supply). • In contrast, many alternative sources of energy are renewable resources (their supplies are refreshed faster than humans consume them). • Examples: wind, solar, hydropower

  13. Challenges in changing to renewable sources Changing to a new resource type involves: • Discovery (e.g. of new mineral deposit) and developing a new technology. • Altering systems that produce, process, and distribute these resources. • Ex: mining, processing, refining, and delivery represent billions of dollars in complex infrastructure Energy facilities typically operate for 30 - 50 years and cannot change overnight. Retiring them prematurely can be costly.

  14. Example: off-shore oil drilling • Supplies/personnel transported to/from platform • Sand removal/oil extraction • Oil tankers or pipelines to transport oil • Refining Offshore oil drilling platform, Gulf of Mexico

  15. Thinking about supply • Energy resources are central to human existence • When will we run out of oil? • Declining fossil fuel supply drives innovation • Best oil deposits are exploited first, followed by lower-quality sources as demand rises. • As demand increases, supply decreases, the price rises: • reduces demand • incentive to develop lower-quality or costly sources, and improve technologies for obtaining more • spurs development of alternatives

  16. Today, high oil prices are driving investments into fuel production from plant sources Pump offering bio-based fuels, Santa Fe, New Mexico

  17. Stock and flow of non-renewable sources • Stock - amount of material in a certain deposit or reservoir that can be recovered with today's technology (example: the total quantity of oil in a field) • Flow - rate at which new material is added to the stock (inflow) or removed from the stock (outflow). • Net flow rate - (inflow minus outflow) determines whether the stock grows, shrinks, or remains constant.

  18. Estimating Natural Gas Stock

  19. Fossil Fuels • Coal, oil, natural gas • Energy (carbon) stored in plant tissues by photosynthesis millions of years ago • Ancient plants and animals died, were buried in sediments over time • Earth's heat and compression from the weight of overlying sediment/rock eventually turned these deposits into coal, oil, and natural gas.

  20. Coal • The first fossil fuel exploited by humans • A carbon-rich rock formed from buried plants in ancient forests or swamps. • Plants are converted to peat—a loose, brown, organically rich soil • As more rock layers press down on the buried deposits, geothermal energy heats the peat and reduces its oxygen and hydrogen content, converting it to coal • As materials go through this process, known as thermal maturation, their energy content by weight increases.

  21. Coal • Brown coal (lignite) – younger coal, low energy content, (more needed relative to higher-grade coals in order to generate the same amount of power) • Sub-bituminous coal and bituminous coal - dark black, most important coal grade for energy production • Anthracite coals - gray, very high energy content. Most accessible reserves in the US have been exhausted.

  22. Environmental Impacts of Coal Mining • Underground mines • Hazardous • Mine collapse • Coal dust and methane gas (commonly found with coal) raise risk of explosions. • Worldwide, several thousand miners on average die each year in coal mining-related accidents.

  23. Environmental Impacts of Coal Mining Strip mines • removing soils and overburden to extract shallow coal • leave permanent scars on the landscape. • mountaintop removal: land is clear-cut and leveled to expose coal seams

  24. Environmental Impacts of Coal Mining • Acid drainage (underground and strip mines) • Coal contains sulfur, • when rain or groundwater comes in contact with coal, it produces sulfuric acid. • can pollute surrounding areas long after the mines are shut down. • Many underground mines are below the water table and flood often; contaminated water flows out of mines, lowering the pH of lakes, rivers, and streams and leaching toxic heavy metals from the ground. • Major source of pollution in WV and PA

  25. Environmental Impacts of Coal Combustion • produces significant amounts of atmospheric pollution and greenhouse gas emissions • sulfate and nitrogen emissions contribute to acid deposition, regional haze, and smog. • produces mercury • technologies to ‘clean’ coal and re-capture carbon lost to atmosphere under development, but currently expensive

  26. Oil and Natural Gas • from ancient sea beds • marine organisms die, settle to the seafloor in anaerobic environments (no oxygen) where they are preserved, buried by sediments and heated to form hydrocarbons • Hydrocarbons –organic compounds consisting of carbon and hydrogen atoms

  27. 1. Drilling Predicting the location, type, and quality of hydrocarbon systems is critical oil and gas development.

  28. 2. Processing Oil • Refineries distill crude oil to produce different fuels • about 1/2 barrel of oil (42 gallons) converted to gasoline. • also yields kerosene, jet fuel, diesel fuel, home heating oil, and lubricants in varying proportions Natural Gas • may require processing to remove undesirable gases and other impurities. • In some cases this process can yield useful byproducts, such as sulfur, which is sold and used to generate fertilizer and for a wide range of other industrial purposes.

  29. 3. Environmental Effects • drilling pads, access roads disturbs ecosystems • contamination of aquifers from drilling • Offshore drilling can cause spills, leaks that pollute ocean waters • Transporting oil and gas subject to spills. • Oil produces lower levels of CO2, sulfur dioxide, nitrogen oxide, and mercury than coal • Natural gas combustion emits lower amounts of nitrogen oxide and CO2 and virtually no sulfur dioxide or mercury. • Drilling has moved into environmentally sensitive regions, public lands that are home to rare and endangered species

  30. Nuclear Power • generates 6% total global energy consumption • produced by enhancing the radioactive decay of fissile materials—elements whose atoms can be split, releases energy. • 0.7 % of natural uranium consists of the isotope uranium-235 - radioactive, fissile and is the most widely-used fuel in standard nuclear reactors.

  31. Nuclear Power • companies mine uranium ore and, by uranium enrichment, increase the concentration of U-235 to 4% • Enriched uranium formed into fuel rods, placed inside a nuclear reactor and bombarded by neutrons. • U-235 atoms split into two or more smaller atoms • releases large amounts of energy • also releases excess neutrons, which split other U-235 atoms, causing a nuclear fission chain reaction.

  32. Operators control rate of fission using control rods and moderators that absorb excess neutrons and by adjusting the reactor temperature, which affects the reaction rate. • Energy generated in the reactor heats water, steam, or other fluid, which is used to produce steam that drives electric turbines

  33. Problems with Nuclear Power US >100 nuclear power reactors, but no new reactors ordered since 1978 • Shoreham plant closed 1989 without ever generating electric power Major concern is safety • Nuclear accidents: • Three Mile Island, 1979 • Chernobyl, 1986; estimated ~4000 eventual deaths, many more times that in health problems • Can cause radiation exposure, causes cancer

  34. Problems with Nuclear Power Storage of radioactive waste • Spent fuel rods remain highly radioactive for thousands of years • Delay of nuclear waste storage facility, Yucca Mountain, NV • Concerns that waste will not be isolated from the environment • Many nuclear plants store waste onsite Main tunnel shaft descends >5 miles into Yucca Mountain.

  35. Problems with Nuclear Power • Facilitates development of nuclear weapons • Technology that enriches uranium to 4% U-235 can be used to enrich uranium to 90% U-235 or higher • Used to make nuclear weapons. • Nuclear power produces plutonium, also used in weapons

  36. Renewable Energy Sources

  37. Biomass Energy • Most is low-tech in developing countries (includes wood-burning stoves) • Inefficient and high impact (produces air pollution) • Burning plants and plant-derived material (agricultural crops and wastes, trees, forestry wastes), animal wastes and municipal solid waste. • Newer, more efficient, cleaner biomass technologies . . .

  38. Biomass Ethanol • fermented from corn and other crops • Used as a gasoline additive (~10%) Biodiesel • From vegetable oil, soybeans, or other crops • can be used in place of diesel (and is cleaner) Problems: requires a lot of energy to make! • requires fuel to make fertilizer, run farm machines, transport fuel • no significant net energy savings over gasoline and diesel • growing corn is water-intensive and removes significant levels of nutrients from soil • Heavy reliance on these sources could divert crops from the food supply

  39. Cellulosic Ethanol • Cellulose – indigestible plant material • Carbon-rich (produces more energy than same amount of corn) • Cellulose is tough and must be broken down before it can be fermented • Examples: switchgrass, corn stalks

  40. Hydropower and Ocean Energy • generates about 17% of world electricity • power of flowing water used to generate electricity • River dams, • placing turbines ocean areas with significant tides and currents • Low pollution emissions

  41. Falling water flows through pipes (penstocks), then turns turbine blades, spins generator, produces electricity Negative environmental impacts of dams: • Kill plants, displacing animals • Alter river flow, stream beds, river banks; • Modify water temperature, oxygen and nutrients • Reduce transport of nutrients and sediments below dams • Block migration of fish Limited future: only a few good sites available for development (Africa, Asia, and Latin America)

  42. Wind Energy • Wind turbines directly harness wind power and convert it to electricity. • generates < 0.5% world's electricity supply • but high growth potential • best locations are areas with consistently high winds where large turbines can be situated • can be located on land and in shallow offshore waters • LI Offshore Wind Power Project

  43. Wind Energy Pros and cons • Do not produce air pollutants or greenhouse gases • May impact birds and bats • Can be visually disruptive • Others . . .

  44. Geothermal Energy • Energy companies can drill a mile or more to tap underground reserves of steam/hot water, drives electric turbines to generate electricity • renewable because it draws from unlimited heat of the Earth's interior • virtually no atmospheric pollutants or greenhouse gas emissions. • US resources are located west of the Mississippi River

  45. U.S. geothermal resources (est. temperature at 6 km depth) Unreliable for eastern US because high electricity demand and the local geology does not provide sufficiently high subsurface temperatures.

  46. Solar Energy Photovoltaic (PV) systems - sunlight hits PV cells, material produces electrons creating an electric current. - can be used in wide range of climates and latitudes - residential systems are now common - needs improvement with efficiency Solar concentrating systems -focus sunlight with mirrors to heat a liquid that boils water, creating steam to turn a turbine that generates electricity • best for power plants in areas with strong sunlight and clear skies

  47. Hydrogen Power Fuel of the Future? • Hydrogen stripped from fossil fuels (CH) or by splitting water (H20) using electricity or heat • Costs: process uses lots of electricity or fuel energy; deriving H from fossil fuels emits CO2 • Benefits: portable, storable, can be used in highly efficient combustion engines or fuel cells, low emissions. • hydrogen fuel cells to power cars

  48. Necessity is the mother of invention.

More Related