Portal:Energy
Energy is a property of objects and systems of objects to act against a force (to do work), explored in branches of physics such as thermodynamics. Popularly the term is most often used in the context of energy as a public technology: energy resources, their consumption, development, depletion, and conservation. Biologically, bodies rely on food for energy in the same sense as industry relies on fuels to continue functioning. Since economic activities such as manufacturing and transportation can be energy intensive, energy efficiency, energy dependence, energy security and price are key concerns. Increased awareness of the effects of global warming has led to global debate and action for the reduction of greenhouse gases emissions; like many previous energy use patterns, it is changing not due to depletion or supply constraints but due to problems with waste, extraction, or geopolitical scenarios. First, somehow there is a movement. There happened to be a burst of motion first. Motion implies and embraces energy, includes energy in itself. That first movement is a systematic one. The energy is the “ability of that system to perform work.” After that first movement we have the energy to play with. The universe is the result of the work systematically performed by that burst of motion. Motion can be transferred, transformed and converted into different forms. Whenever we see or sense a work done that means a visible energy. From here on radiation of energy, electromagnetic radiation and so on is easy to follow. In the context of natural science, energy can take several different forms: thermal, chemical, electrical, radiant, nuclear, etc. These are often grouped as being either kinetic energy or potential energy. Many of these forms can be readily transformed into another with the help of a device - from chemical energy to electrical energy using a battery, for example. Most energy available for human use ultimately comes from the sun, which generates it with nuclear fusion. The enormous potential for fusion and other basic nuclear reactions is expressed by the equation E = mc2. The concepts of energy and its transformations are useful in explaining natural processes on larger scales: Meteorological phenomena like wind, rain, lightning and tornadoes all result from energy transformations brought about by solar energy on the planet. Life itself is critically dependent on biological energy transformations; organic chemical bonds are constantly broken and made to make the exchange and transformation of energy possible. Read more... Template:/box-footer
On 11 March 2011 the Fukushima Daiichi nuclear disaster began, following the 2011 Tōhoku earthquake and tsunami off the northeast coast of Japan. The tsunami disabled emergency generators required to cool the reactors. Over the following three weeks nuclear meltdowns occurred in units 1, 2 and 3; visible explosions, suspected to be caused by hydrogen gas, in units 1 and 3; a suspected explosion in unit 2, that may have damaged the primary containment vessel; and a possible uncovering of the units 1, 3 and 4 spent fuel pools. 50,000 households were evacuated after radiation leaked into the air, soil and sea. Radiation checks led to bans of some shipments of vegetables and fish.
On 5 July 2012, the Japanese National Diet appointed The Fukushima Nuclear Accident Independent Investigation Commission (NAIIC) submitted its inquiry report to the Japanese Diet. The Commission found the nuclear disaster was "manmade", that the direct causes of the accident were all foreseeable prior to 11 March 2011. The report also found that the Fukushima Daiichi Nuclear Power Plant was incapable of withstanding the earthquake and tsunami. The Fukushima disaster was the worst nuclear accident in 25 years. The events at units 1, 2 and 3 have been rated at Level 7 (major release of radioactive material with widespread health and environmental effects requiring implementation of planned and extended countermeasures) on the International Nuclear Event Scale. Read more... Photo credit: Diliff
Benjamin K. Sovacool is Director of the Danish Center for Energy Technology at AU Herning and a Professor of Social Sciences at Aarhus University in Denmark. He is also Associate Professor at Vermont Law School and Director of the Energy Security and Justice Program at their Institute for Energy and the Environment. Sovacool's research interests include energy policy, environmental issues, and science and technology policy, and his research has taken him to 50 countries. He is the author or editor of sixteen books and 250 peer reviewed academic articles. Sovacool's work has been referred to in academic publications such as Science, Nature, and Scientific American. He has written opinion editorials for the Wall Street Journal and the San Francisco Chronicle. Sovacool is a Intergovernmental Panel on Climate Change Contributing Author. Read More...
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