Categories: EnergyEnvironment

Alternative energy

Alternative energy is any energy source that is an alternative to fossil fuel. These alternatives are intended to address concerns about fossil fuels, such as its high carbon dioxide emissions, an important factor in global warming. Marine energy, hydroelectric, wind, geothermal and solar power are all alternative sources of energy.

The nature of what constitutes an alternative energy source has changed considerably over time, as have controversies regarding energy use. Because of the variety of energy choices and differing goals of their advocates, defining some energy types as “alternative” is considered very controversial.

Existing types of alternative energy
Hydro electricity captures energy from falling water.
Nuclear energy uses nuclear fission to release energy stored in the atomic bonds of heavy elements.
Wind energy is the generation of electricity from wind, commonly by using propeller-like turbines.
Solar energy is the use of energy from the sun. Heat from the sun can be used for solar thermal applications or light can be converted into electricity via photovoltaic devices.
Geothermal energy is the use of the earth’s internal heat to boil water for heating buildings or generating electricity.
Biofuel and ethanol are plant-derived gasoline substitutes for powering vehicles.
Hydrogen can be used as a carrier of energy, produced by various technologies such as cracking of hydrocarbons or water electrolysis.

Enabling technologies
Ice storage air conditioning and thermal storage heaters are methods of shifting consumption to use low cost off-peak electricity. When compared to resistance heating, heat pumps conserve electrical power (or in rare cases mechanical or thermal power) by collecting heat from a cool source such as a body of water, the ground or the air.

Thermal storage technologies allow heat or cold to be stored for periods of time ranging from diurnal to interseasonal, and can involve storage of sensible energy (i.e. by changing the temperature of a medium) or latent energy (e.g. through phase changes of a medium (i.e. changes from solid to liquid or vice versa), such as between water and slush or ice). Energy sources can be natural (via solar-thermal collectors, or dry cooling towers used to collect winter’s cold), waste energy (such as from HVAC equipment, industrial processes or power plants), or surplus energy (such as seasonally from hydropower projects or intermittently from wind farms). The Drake Landing Solar Community (Alberta, Canada) is illustrative. Borehole thermal energy storage allows the community to get 97% of its year-round heat from solar collectors on the garage roofs. The storages can be insulated tanks, borehole clusters in substrates ranging from gravel to bedrock, deep aquifers, or shallow pits that are lined and insulated. Some applications require inclusion of a heat pump.

Renewable energy vs non-renewable energy
Renewable energy is generated from natural resources—such as sunlight, wind, rain, tides and geothermal heat—which are renewable (naturally replenished). When comparing the processes for producing energy, there remain several fundamental differences between renewable energy and fossil fuels. The process of producing oil, coal, or natural gas fuel is a difficult and demanding process that requires a great deal of complex equipment, physical and chemical processes. On the other hand, alternative energy can be widely produced with basic equipment and natural processes. Wood, the most renewable and available alternative fuel, emits the same amount of carbon when burned as would be emitted if it degraded naturally. Nuclear power is an alternative to fossil fuels that is non-renewable, like fossil fuels, nuclear ones are a finite resource.

Ecologically friendly alternatives
A renewable energy source such as biomass is sometimes regarded as a good alternative to providing heat and electricity with fossil fuels. Biofuels are not inherently ecologically friendly for this purpose, while burning biomass is carbon-neutral, air pollution is still produced. For example, the Netherlands, once leader in use of palm oil as a biofuel, has suspended all subsidies for palm oil due to the scientific evidence that their use “may sometimes create more environmental harm than fossil fuels”. The Netherlands government and environmental groups are trying to trace the origins of imported palm oil, to certify which operations produce the oil in a responsible manner. Regarding biofuels from foodstuffs, the realization that converting the entire grain harvest of the US would only produce 16% of its auto fuel needs, and the decimation of Brazil’s CO2 absorbing tropical rain forests to make way for biofuel production has made it clear that placing energy markets in competition with food markets results in higher food prices and insignificant or negative impact on energy issues such as global warming or dependence on foreign energy. Recently, alternatives to such undesirable sustainable fuels are being sought, such as commercially viable sources of cellulosic ethanol.

Relatively new concepts for alternative energy

Carbon-neutral and negative fuels
Carbon-neutral fuels are synthetic fuels (including methane, gasoline, diesel fuel, jet fuel or ammonia) produced by hydrogenating waste carbon dioxide recycled from power plant flue-gas emissions, recovered from automotive exhaust gas, or derived from carbonic acid in seawater. Commercial fuel synthesis companies suggest they can produce synthetic fuels for less than petroleum fuels when oil costs more than $55 per barrel. Renewable methanol (RM) is a fuel produced from hydrogen and carbon dioxide by catalytic hydrogenation where the hydrogen has been obtained from water electrolysis. It can be blended into transportation fuel or processed as a chemical feedstock.

The George Olah carbon dioxide recycling plant operated by Carbon Recycling International in Grindavík, Iceland has been producing 2 million liters of methanol transportation fuel per year from flue exhaust of the Svartsengi Power Station since 2011. It has the capacity to produce 5 million liters per year. A 250 kilowatt methane synthesis plant was constructed by the Center for Solar Energy and Hydrogen Research (ZSW) at Baden-Württemberg and the Fraunhofer Society in Germany and began operating in 2010. It is being upgraded to 10 megawatts, scheduled for completion in autumn, 2012. Audi has constructed a carbon-neutral liquefied natural gas (LNG) plant in Werlte, Germany. The plant is intended to produce transportation fuel to offset LNG used in their A3 Sportback g-tron automobiles, and can keep 2,800 metric tons of CO2 out of the environment per year at its initial capacity. Other commercial developments are taking place in Columbia, South Carolina, Camarillo, California, and Darlington, England.

Such fuels are considered carbon-neutral because they do not result in a net increase in atmospheric greenhouse gases. To the extent that synthetic fuels displace fossil fuels, or if they are produced from waste carbon or seawater carbonic acid, and their combustion is subject to carbon capture at the flue or exhaust pipe, they result in negative carbon dioxide emission and net carbon dioxide removal from the atmosphere, and thus constitute a form of greenhouse gas remediation.

Such renewable fuels alleviate the costs and dependency issues of imported fossil fuels without requiring either electrification of the vehicle fleet or conversion to hydrogen or other fuels, enabling continued compatible and affordable vehicles. Carbon-neutral fuels offer relatively low cost energy storage, alleviating the problems of wind and solar intermittency, and they enable distribution of wind, water, and solar power through existing natural gas pipelines.

Nighttime wind power is considered the most economical form of electrical power with which to synthesize fuel, because the load curve for electricity peaks sharply during the day, but wind tends to blow slightly more at night than during the day, so, the price of nighttime wind power is often much less expensive than any alternative. Germany has built a 250 kilowatt synthetic methane plant which they are scaling up to 10 megawatts.

Algae fuel
Algae fuel is a biofuel which is derived from algae. During photosynthesis, algae and other photosynthetic organisms capture carbon dioxide and sunlight and convert it into oxygen and biomass. This is usually done by placing the algae between two panes of glass. The algae creates three forms of energy fuel: heat (from its growth cycle), biofuel (the natural “oil” derived from the algae), and biomass (from the algae itself, as it is harvested upon maturity).

The heat can be used to power building systems (such as heat process water) or to produce energy. Biofuel is oil extracted from the algae upon maturity, and used to create energy similar to the use of biodiesel. The biomass is the matter left over after extracting the oil and water, and can be harvested to produce combustible methane for energy production, similar to the warmth felt in a compost pile or the methane collected from biodegradable materials in a landfill. Additionally, the benefits of algae biofuel are that it can be produced industrially, as well as vertically (i.e. as a building facade), thereby obviating the use of arable land and food crops (such as soy, palm, and canola).

Biomass briquettes
Biomass briquettes are being developed in the developing world as an alternative to charcoal. The technique involves the conversion of almost any plant matter into compressed briquettes that typically have about 70% the calorific value of charcoal. There are relatively few examples of large scale briquette production. One exception is in North Kivu, in eastern Democratic Republic of Congo, where forest clearance for charcoal production is considered to be the biggest threat to Mountain Gorilla habitat. The staff of Virunga National Park have successfully trained and equipped over 3500 people to produce biomass briquettes, thereby replacing charcoal produced illegally inside the national park, and creating significant employment for people living in extreme poverty in conflict affected areas.

Biogas digestion
Biogas digestion harnesses the methane gas that is released when organic waste breaks down in an anaerobic environment. This gas can be retrieved from landfill sites or sewage systems. The gas can be used as a fuel for heat or, more commonly, electricity generation. The methane gas that is collected and refined can be used as an energy source for various products.

Biological hydrogen production
Hydrogen gas is a completely clean burning fuel; its only by-product is water. It also contains relatively high amount of energy compared with other fuels due to its chemical structure.

2H2 + O2 → 2H2O + High Energy

High Energy + 2H2O → 2H2 + O2

This requires a high-energy input, making commercial hydrogen very inefficient. Use of a biological vector as a means to split water, and therefore produce hydrogen gas, would allow for the only energy input to be solar radiation. Biological vectors can include bacteria or more commonly algae. This process is known as biological hydrogen production. It requires the use of single celled organisms to create hydrogen gas through fermentation. Without the presence of oxygen, also known as an anaerobic environment, regular cellular respiration cannot take place and a process known as fermentation takes over. A major by-product of this process is hydrogen gas. If this could be implemented on a large scale, then sunlight, nutrients and water could create hydrogen gas to be used as a dense source of energy. Large-scale production has proven difficult. Not until 1999, was it even possible to induce these anaerobic conditions by sulfur deprivation. Since the fermentation process is an evolutionary back up, turned on during stress, the cells would die after a few days. In 2000, a two-stage process was developed to take the cells in and out of anaerobic conditions and therefore keep them alive. For the last ten years, finding a way to do this on a large-scale has been the main goal of research. Careful work is being done to ensure an efficient process before large-scale production, however once a mechanism is developed, this type of production could solve our energy needs.

Hydroelectricity
Hydroelectricity provided 75% of the worlds renewable electricity in 2013. Much of the electricity used today is a result of the heyday of conventional hydroelectric development between 1960 and 1980, which has virtually ceased in Europe and North America due to environmental concerns. Globally there is a trend towards more hydroelectricity. From 2004 to 2014 the installed capacity rose from 715 to 1,055 GW. A popular alternative to the large dams of the past is run-of-the-river where there is no water stored behind a dam and generation usually varies with seasonal rainfall. Using run-of-the-river in wet seasons and solar in dry seasons can balance seasonal variations for both. Another move away from large dams is small hydro, these tend to be situated high up on tributaries, rather than on main rivers in valley bottoms.

Offshore wind
Offshore wind farms are similar to land-based wind farms, but are located on the ocean. Offshore wind farms can be placed in water up to 40 metres (130 ft) deep, whereas floating wind turbines can float in water up to 700 metres (2,300 ft) deep. The advantage of having a floating wind farm is to be able to harness the winds from the open ocean. Without any obstructions such as hills, trees and buildings, winds from the open ocean can reach up to speeds twice as fast as coastal areas.

Significant generation of offshore wind energy already contributes to electricity needs in Europe and Asia and now the first offshore wind farms are under development in U.S. waters. While the offshore wind industry has grown dramatically over the last several decades, especially in Europe, there is still uncertainty associated with how the construction and operation of these wind farms affect marine animals and the marine environment.

Traditional offshore wind turbines are attached to the seabed in shallower waters within the nearshore marine environment. As offshore wind technologies become more advanced, floating structures have begun to be used in deeper waters where more wind resources exist.

Marine and hydrokinetic energy
Marine and Hydrokinetic (MHK) or marine energy development includes projects using the following devices:

Wave power is the transport of energy by wind waves, and the capture of that energy to do useful work – for example, electricity generation or pumping water into reservoirs. A machine able to exploit significant waves in open coastal areas is generally known as a wave energy converter.
Tidal power turbines are placed in coastal and estuarine areas and daily flows are quite predictable.
In-stream turbines in fast-moving rivers
Ocean current turbines in areas of strong marine currents
Ocean thermal energy converters in deep tropical waters.

Nuclear power
In the year 2015 ten new reactors came online and 67 more were under construction including the first eight new Generation III+ AP1000 reactors in the US and China and the first four new Generation III EPR reactors in Finland, France and China. Reactors are also under construction in Belarus, Brazil, India, Iran, Japan, Pakistan, Russia, Slovakia, South Korea, Turkey, Ukraine and United Arab Emirates.

Thorium nuclear power
Thorium is a fissionable material for possible future use in a thorium-based reactor. Proponents of thorium reactors claims several potential advantages over a uranium fuel cycle, such as thorium’s greater abundance, better resistance to nuclear weapons proliferation, and reduced plutonium and actinide production. Thorium reactors can be modified to produce Uranium-233, which can then be processed into highly enriched uranium, which has been tested in low yield weapons, and is unproven on a commercial scale.

Investing in alternative energy
As an emerging economic sector, there are limited stock market investment opportunities in alternative energy available to the general public. The public can buy shares of alternative energy companies from various stock markets, with wildly volatile returns. The recent IPO of SolarCity demonstrates the nascent nature of this sector- within a few weeks, it already had achieved the second highest market cap within the alternative energy sector.

Related Post

Investors can also choose to invest in ETFs (exchange-traded funds) that track an alternative energy index, such as the WilderHill New Energy Index. Additionally, there are a number of mutual funds, such as Calvert’s Global Alternative Energy Mutual Fund that are a bit more proactive in choosing the selected investments.

The economics of solar PV electricity are highly dependent on silicon pricing and even companies whose technologies are based on other materials (e.g., First Solar) are impacted by the balance of supply and demand in the silicon market. In addition, because some companies sell completed solar cells on the open market (e.g., Q-Cells), this creates a low barrier to entry for companies that want to manufacture solar modules, which in turn can create an irrational pricing environment.

In contrast, because wind power has been harnessed for over 100 years, its underlying technology is relatively stable. Its economics are largely determined by siting (e.g., how hard the wind blows and the grid investment requirements) and the prices of steel (the largest component of a wind turbine) and select composites (used for the blades). Because current wind turbines are often in excess of 100 meters high, logistics and a global manufacturing platform are major sources of competitive advantage. These issues and others were explored in a research report by Sanford Bernstein.

Alternative energy in transportation
Due to steadily rising gas prices in 2008 with the US national average price per gallon of regular unleaded gas rising above $4.00 at one point, there has been a steady movement towards developing higher fuel efficiency and more alternative fuel vehicles for consumers. In response, many smaller companies have rapidly increased research and development into radically different ways of powering consumer vehicles. Hybrid and battery electric vehicles are commercially available and are gaining wider industry and consumer acceptance worldwide.

For example, Nissan USA introduced the world’s first mass-production electric vehicle, the Nissan Leaf. A plug-in hybrid car, the Chevrolet Volt also has been produced, using an electric motor to drive the wheels, and a small four-cylinder engine to generate additional electricity.

Making alternative energy mainstream
Before alternative energy becomes mainstream there are a few crucial obstacles that it must overcome. First there must be increased understanding of how alternative energies are beneficial; secondly the availability components for these systems must increase; and lastly the pay-back period must be decreased.

For example, electric vehicles (EV) and plug-in hybrid electric vehicles (PHEV) are on the rise. The continue adoption of these vehicles depend on investment in public charging infrastructure, as well as implementing much more alternative energy for future transportation.

Research
There are numerous organizations within the academic, federal, and commercial sectors conducting large scale advanced research in the field of alternative energy. This research spans several areas of focus across the alternative energy spectrum. Most of the research is targeted at improving efficiency and increasing overall energy yields.

In the US, multiple federally supported research organizations have focused on alternative energy in recent years. Two of the most prominent of these labs are Sandia National Laboratories and the National Renewable Energy Laboratory (NREL), both of which are funded by the United States Department of Energy and supported by various corporate partners. Sandia has a total budget of $2.4 billion while NREL has a budget of $375 million.

With the increasing consumption levels of energy, it is projected that the levels would increase by 21% in 2030. The cost of the renewables was relatively cheaper at $2.5m/MW as compared to the non-renewables & 2.7m/MW. Evidently, the use of renewable energy is a cost effective method of obtaining energy. Additionally, their use also dispenses with the trade-off that has existed between environmental conservation and economic growth.

Mechanical energy
Mechanical energy associated with human activities such as blood circulation, respiration, walking, typing and running, is ubiquitous but usually wasted. It has attracted tremendous attention from researchers around the globe to find methods to scavenge such mechanical energies. The best solution currently is to use piezoelectric materials, which can generate flow of electrons when deformed. Various devices using piezoelectric materials have been built to scavenge mechanical energy. Considering that the piezoelectric constant of the material plays a critical role in the overall performance of a piezoelectric device, one critical research direction to improve device efficiency is to find new material of large piezoelectric response. Lead Magnesium Niobate-Lead Titanate (PMN-PT) is a next-generation piezoelectric material with super high piezoelectric constant when ideal composition and orientation are obtained. In 2012, PMN-PT Nanowires with a very high piezoelectric constant were fabricated by a hydro-thermal approach and then assembled into an energy-harvesting device. The record-high piezoelectric constant was further improved by the fabrication of a single-crystal PMN-PT nanobelt, which was then used as the essential building block for a piezoelectric nanogenerator.

Solar
Solar energy can be used for heating, cooling or electrical power generation using the sun.

Solar heat has long been employed in passively and actively heated buildings, as well as district heating systems. Examples of the latter are the Drake Landing Solar Community is Alberta, Canada, and numerous district systems in Denmark and Germany. In Europe, there are two programs for the application of solar heat: the Solar District Heating (SDH) and the International Energy Agency’s Solar Heating and Cooling (SHC) program.

The obstacles preventing the large-scale implementation of solar powered energy generation is the inefficiency of current solar technology and the cost. Currently, photovoltaic (PV) panels only have the ability to convert around 16% of the sunlight that hits them into electricity.

Both Sandia National Laboratories and the National Renewable Energy Laboratory (NREL), have heavily funded solar research programs. The NREL solar program has a budget of around $75 million and develops research projects in the areas of photovoltaic (PV) technology, solar thermal energy, and solar radiation. The budget for Sandia’s solar division is unknown, however it accounts for a significant percentage of the laboratory’s $2.4 billion budget.

Several academic programs have focused on solar research in recent years. The Solar Energy Research Center (SERC) at University of North Carolina (UNC) has the sole purpose of developing a cost-effective solar technology. In 2008, researchers at Massachusetts Institute of Technology (MIT) developed a method to store solar energy by using it to produce hydrogen fuel from water. Such research is targeted at addressing the obstacle that solar development faces of storing energy for use during nighttime hours when the sun is not shining. The Zhangebei National Wind and Solar Energy Storage and Transmission Demonstration Project northwest of Beijing, uses batteries to store 71 MWh, integrating wind and solar energy on the grid with frequency and voltage regulation.

In February 2012, North Carolina-based Semprius Inc., a solar development company backed by German corporation Siemens, announced that they had developed the world’s most efficient solar panel. The company claims that the prototype converts 33.9% of the sunlight that hits it to electricity, more than double the previous high-end conversion rate.

Wind
Wind energy research dates back several decades to the 1970s when NASA developed an analytical model to predict wind turbine power generation during high winds. Today, both Sandia National Laboratories and National Renewable Energy Laboratory have programs dedicated to wind research. Sandia’s laboratory focuses on the advancement of materials, aerodynamics, and sensors. The NREL wind projects are centered on improving wind plant power production, reducing their capital costs, and making wind energy more cost effective overall.

The Field Laboratory for Optimized Wind Energy (FLOWE) at Caltech was established to research alternative approaches to wind energy farming technology practices that have the potential to reduce the cost, size, and environmental impact of wind energy production.

Renewable energies such as wind, solar, biomass and geothermal combined, supplied 1.3% of global final energy consumption in 2013.

Biomass
Biomass can be regarded as “biological material” derived from living, or recently living organisms. It most often refers to plants or plant-derived materials which are specifically called lignocellulosic biomass. As an energy source, biomass can either be used directly via combustion to produce heat, or indirectly after converting it to various forms of biofuel. Conversion of biomass to biofuel can be achieved by different methods which are broadly classified into: thermal, chemical, and biochemical methods. Wood remains the largest biomass energy source today; examples include forest residues (such as dead trees, branches and tree stumps), yard clippings, wood chips and even municipal solid waste. In the second sense, biomass includes plant or animal matter that can be converted into fibers or other industrial chemicals, including biofuels. Industrial biomass can be grown from numerous types of plants, including miscanthus, switchgrass, hemp, corn, poplar, willow, sorghum, sugarcane, bamboo, and a variety of tree species, ranging from eucalyptus to oil palm (palm oil).

Biomass, biogas and biofuels are burned to produce heat/power and in doing so harm the environment. Pollutants such as sulphurous oxides (SOx), nitrous oxides (NOx), and particulate matter (PM) are produced from this combustion. The World Health Organisation estimates that 7 million premature deaths are caused each year by air pollution, and biomass combustion is a major contributor of it. The use of biomas is carbon neutral over time, but is otherwise similar to burning fossil fuels.

Ethanol biofuels
As the primary source of biofuels in North America, many organizations are conducting research in the area of ethanol production. On the Federal level, the USDA conducts a large amount of research regarding ethanol production in the United States. Much of this research is targeted toward the effect of ethanol production on domestic food markets.

The National Renewable Energy Laboratory has conducted various ethanol research projects, mainly in the area of cellulosic ethanol. Cellulosic ethanol has many benefits over traditional corn based-ethanol. It does not take away or directly conflict with the food supply because it is produced from wood, grasses, or non-edible parts of plants. Moreover, some studies have shown cellulosic ethanol to be more cost effective and economically sustainable than corn-based ethanol. Sandia National Laboratories conducts in-house cellulosic ethanol research and is also a member of the Joint BioEnergy Institute (JBEI), a research institute founded by the United States Department of Energy with the goal of developing cellulosic biofuels.

Other biofuels
From 1978 to 1996, the National Renewable Energy Laboratory experimented with using algae as a biofuels source in the “Aquatic Species Program.” A self-published article by Michael Briggs, at the University of New Hampshire Biofuels Group, offers estimates for the realistic replacement of all motor vehicle fuel with biofuels by utilizing algae that have a natural oil content greater than 50%, which Briggs suggests can be grown on algae ponds at wastewater treatment plants. This oil-rich algae can then be extracted from the system and processed into biofuels, with the dried remainder further reprocessed to create ethanol.

The production of algae to harvest oil for biofuels has not yet been undertaken on a commercial scale, but feasibility studies have been conducted to arrive at the above yield estimate. In addition to its projected high yield, algaculture— unlike food crop-based biofuels — does not entail a decrease in food production, since it requires neither farmland nor fresh water. Many companies are pursuing algae bio-reactors for various purposes, including scaling up biofuels production to commercial levels.

Several groups in various sectors are conducting research on Jatropha curcas, a poisonous shrub-like tree that produces seeds considered by many to be a viable source of biofuels feedstock oil. Much of this research focuses on improving the overall per acre oil yield of Jatropha through advancements in genetics, soil science, and horticultural practices. SG Biofuels, a San Diego-based Jatropha developer, has used molecular breeding and biotechnology to produce elite hybrid seeds of Jatropha that show significant yield improvements over first generation varieties. The Center for Sustainable Energy Farming (CfSEF) is a Los Angeles-based non-profit research organization dedicated to Jatropha research in the areas of plant science, agronomy, and horticulture. Successful exploration of these disciplines is projected to increase Jatropha farm production yields by 200-300% in the next ten years.

Geothermal
Geothermal energy is produced by tapping into the heat within the earths crust. It is considered sustainable because that thermal energy is constantly replenished. However, the science of geothermal energy generation is still young and developing economic viability. Several entities, such as the National Renewable Energy Laboratory and Sandia National Laboratories are conducting research toward the goal of establishing a proven science around geothermal energy. The International Centre for Geothermal Research (IGC), a German geosciences research organization, is largely focused on geothermal energy development research.

Hydrogen
Over $1 billion has been spent on the research and development of hydrogen fuel in the United States. Both the National Renewable Energy Laboratory and Sandia National Laboratories have departments dedicated to hydrogen research. Much of this work centers on hydrogen storage and fuel cell technologies

Source from Wikipedia

Share