As we enter the 21st century the average human's life is dictated by the production and quantity of energy. This energy is produced in many different forms, from fossil fuel to hydro and solar power. Though this production of energy has sufficed up till now, a realization has occurred that the depletion of our current sources is imminent. As a result of this energy crisis, a race to find an alternative energy supply has been put forth. Through plasma fusion's nearly inexhaustible supply of fuel, its lack of greenhouse gases and the amazing spin-off technologies that have developed through plasma research, it is the answer to the current energy crises.
Fusion
To understand the technology behind plasma fusion, fusion itself must be understood. Fusion is the combining of two or more atoms of low mass, which are initially attracted to each other, to form one atom of greater mass. When two atoms combine to form a single atom, they have fused. This fusing releases a large amount of energy with respect to the amount of mass and energy that was initially put into the reaction. This combination releases energy in the form of light and heat.
Energy is created in a fusion reaction through the loss of atomic mass from the beginning to the end of the reaction. The mass of the two atoms is significantly more than the mass of the new atom, which they fused together to form. This loss of mass is subsequently converted into pure energy in the form of light and heat. The reason for this amazing discovery is that mass is just a concentrated form of energy. This understanding between the relationship of mass and energy was discovered by Albert Einstein and illustrated in his famous equation E=mc^2, where E is energy, m is mass, and c is the speed of light. Through this equation the amount of energy held within a mass can be determined. In a plasma fusion reaction between two hydrogen atoms the decrease in mass is about 4x10^-29 kg. This mass is then converted to energy, equaling 23.9 MeV. "To appreciate the magnitude of this result note that if 1g of [hydrogen] is converted to helium, the energy released… would be worth about $70,000" (Physics for scientist and Engineers 1276).
Fission
In a fission event an example of a reaction at an atomic level is an (A)tomic-bomb. The A-bomb harnesses the power of an atom through an uncontrolled reaction.
The development of atomic bomb boosted the level of understanding in terms of physics and chemistry of that particular time period. Physicists started to realize that stable nuclei can be converted to unstable nuclei. Through such process, they discovered that heavy nuclei can undergo nuclear fission. While testing, they added a neutron to an isotope of Uranium 235. This resulted Uranium 235 to become unstable and break down into Barium and Krypton, releasing two to three more neutrons. The breakdown of Uranium 235 is called “fission”. When the released neutrons attach to other isotopes of Uranium 235, this can result in a chain reaction of fission. For every generation of fission, the amount of fission is doubled, and this resulted in an extreme outburst of energy. The amount of energy released by this process is related to Einstein’s famous equation “E=mc^2” (Wolf).
All these effects were the cause of the discovery of nuclear fission and its properties. Nuclear Fusion Nuclear fusion is the process used by the sun and the stars in our solar system to produce their energy. Fusion involves smashing hydrogen atoms together at high velocities to form helium, and the matter is made into energy.
Albert Einstein predicted that mass could be converted into energy early in the century and was confirmed experimentally by John D. Cockcroft and Ernest Walton in 1932. In 1939, Otto Hahn and Fritz Strassmann discovered that neutrons striking the element uranium caused the atoms to split apart. Physicists found out that among the pieces of a split atom were newly produced neutrons. These might encounter other uranium nuclei, caused them to split, and start a chain reaction. If the chain reaction were limited to a moderate pace, a new source of energy could be the result. The chain reaction could release energy rapidly and with explosive force.
Energy can never be created or destroyed. Energy may be transformed from one form to another, but the total energy of an isolated system is always constant.
Second, the potential amount of energy produced by fusion can greatly outweigh the fission. Initially, there are some disadvantages to fusion. The time and money required to develop technology needed to initiate, contain, and sustain a profitable fusion reaction is costly, but the development is still in its early stages and will continue to advance through the next century. Fission readily creates a chain reaction which must be slowed through use of a moderator to avoid core meltdown, while fusion can only be accomplished at temperatures similar to the centre of stars, about 100 million degrees celsius. The components used in fusion exist in the form of plasma where atoms are divided into electrons and nuclei.
From the book The Warmth of Other Suns, the author Isabel Wilkerson writes of the economic disparity and the abject poverty suffered by African Americans during the reconstruction. “Sharecropping, slavery’s replacement, kept them in debt and still bound to whatever plantation they worked. But one thing had changed. The federal government had taken over the affairs of the South, during a period known as Reconstruction, and the newly freed men were able to exercise rights previously denied them. They could vote, marry, or go to school…even college set-up by northern philanthropists, open businesses, and run for office under the protection of northern troops.”
Therefore, the initial excitement for space-nuclear power sources was quickly ended by uncertain requirements, and the broad range of more feasible technical approaches was researched.
According to Merriam-Webster, nuclear fission is defined as “the splitting of an atomic nucleus resulting in the release of large amounts of energy” (Nuclear Fission). In the book Remembering the Manhattan Project: Perspectives on the Making of the Atomic Bomb and Its Legacy, Richard Rhodes, an American journalist and historian, states that fission was essentially discovered by accident. On December 21, 1938, German physicists, Otto Hahn and Fritz Strassman, were performing an experiment in which they bombarded uranium atoms with neutrons (Rhodes 17). They saw that this procedure created mutated atoms that had strange characteristics. Hahn and Strassman found that the neutrons split the nuclei of the uranium in half producing radioactive barium and krypton (Rhodes 18). Rhodes explains that the physicists observed that the reaction was extremely exothermic, producing about ten times the energy needed for the fission to occur. After publishing their findings, physicists all over the world recreated the experiment. After conducting his own fission experiment, Enrico Fermi, an Italian physicist at Colombia University, said, “A little bomb like that and it would all disappear” (qtd. Rhodes 19). Many of the world’s physicists came to the same conclusion; this reaction could be used to develop an atomic weapon. According to Rhodes, this discovery made the development of atomic weaponry seem essential to many countries because the only way to defend themselves against atomic weapons was to have similar weapons of their own.
The atomic bomb is a powerful, explosive nuclear weapon. It is fueled by the fission of the nuclei of specific amounts of plutonium or uranium, in a chain reaction. The strength of the explosion created by one of these bombs is equal to the strength of an explosion created by thousands of tons of TNT.
One of the biggest and most prevalent problems is the need for clean, renewable, sustainable energy. On the forefront of these problems comes the following solutions: nuclear energy, hydro-electric energy, and photovoltaic energy. With the need for energy in today’s current world, exploring different ways of producing power is necessary. The differences and similarities between nuclear energy and alternative energy are important to look over and examine in depth, so that it is plain to see the positive and negative effects of energy production. To begin, nuclear power is produced by nuclear fission, which is the splitting of an atom to start a chain reaction (“11 Facts”).
an initial energy of about 1 MeV will induce fission is rather low, but can be
Nuclear fusion occurs when two atomic nuclei collide with enough energy to bind together to form one nucleus. Nuclear fusion occurs in the core of our sun, and is the source of its tremendous heat. In the sun hydrogen nuclei, single protons, fuse together and form a new nucleus. In the conversion, a small amount of mass is converted into energy. It is this energy that heats the sun.
With the development of the technology of laser enabled the experiments using laser pulse with a high intensity of the order 〖10〗^22 W/〖cm〗^2. So now it brings the possibility of study the parameters of plasma as well as the atoms. The study related to the laser-plasma interaction involves the self-focusing, which is a very important factor to consider. Because the intensity of such a huge order came from it and high power laser and its applications, harmonic generation, X-ray generation, various laser plasma accelerator are depend upon it. Laser will not diverge up to the Rayleigh length, after this range the beam expands due to the natural diffraction. So laser need a channel for guiding the beam and prevent the diffraction. All phenomena like harmonic generation, relativistic self focusing can be studied in the relativistic nonlinear optical effect.
Nuclear energy is generated by a process called fission. Fission occurs within the reactor of a nuclear power plant when a neutron is fired at an atom of uranium causing it to split and release subsequent neutrons.1 These are able to crash into other uranium atoms causing a chain reaction and releasing a great deal of heat energy.
...ion of fusion power plant when the technology has achieved a certain level. This level will be reach with free market and patents right, which will create incentive for scientist to make innovation. Hopefully, countries, in the future, will find co-operating relationship’ among each other and solve environmental problems.