The rest is absorbed into Earth’s atmosphere. Natural Solar Energy Greenhouse Effect The infrared, visible, and UV waves that reach Earth take part in a process of warming the planet and making life possible-the so-called “greenhouse effect.” About 30 percent of the solar energy that reaches Earth is reflected back into space. The color red has the longest wavelengths (closest to infrared), and violet (closest to UV) the shortest. Sandwiched between infrared and UV is the visible spectrum, which contains all the colors we see on Earth. Most heat from the sun arrives as infrared energy. The sun also emits infrared radiation, whose waves are much lower-frequency. Less potent UV rays travel through the atmosphere, and can cause sunburn. The most harmful UV rays are almost completely absorbed by Earth’s atmosphere. The most high-frequency waves emitted by the sun are gamma rays, X-rays, and ultraviolet radiation (UV rays). The vast majority of electromagnetic waves are invisible to us. In contrast, low-frequency waves have much longer wavelengths. Waves with very short wavelengths repeat themselves several times in a given unit of time, so they are high-frequency. The frequency of a wave represents how many times the wave repeats itself in a certain unit of time. The electromagnetic spectrum exists as waves of different frequencies and wavelengths. The energy, heat, and light from the sun flow away in the form of electromagnetic radiation (EMR). Solar energy warms Earth, causes wind and weather, and sustains plant and animal life. Solar energy is constantly flowing away from the sun and throughout the solar system. Nuclear fusion by the PP chain reaction or CNO cycle releases tremendous amounts of energy in the form of waves and particles. Currently, less than two percent of the sun’s energy is created by the CNO cycle. The CNO cycle also converts hydrogen to helium, but relies on carbon, nitrogen, and oxygen (C, N, and O) to do so. In stars that are about 1.3 times bigger than the sun, the CNO cycle drives the creation of energy. The temperature for these stars is around 4 million degrees on the Kelvin scale (about 4 million degrees Celsius, 7 million degrees Fahrenheit). The PP chain reaction occurs in other stars that are about the size of our sun, and provides them with continuous energy and heat. In its core, the sun fuses about 620 million metric tons of hydrogen every second. This process, known as a PP (proton-proton) chain reaction, emits an enormous amount of energy. Fusion occurs when protons of hydrogen atoms violently collide in the sun’s core and fuse to create a helium atom. Solar energy is created by nuclear fusion that takes place in the sun. (Remember that the radioactive process that a nucleus undergoes is characteristic of the isotope.Solar energy is any type of energy generated by the sun. The first controlled chain reaction was achieved on December 2, 1942, in an experiment supervised by Enrico Fermi in a laboratory underneath the football stadium at the University of Chicago.Īlthough fairly simple in theory, an atomic bomb is difficult to produce, in part because uranium-235, the isotope that undergoes fission, makes up only 0.7% of natural uranium the rest is mostly uranium-238, which does not undergo fission. This is the mechanism behind the atomic bomb. The quick production of energy creates an explosion. A single neutron can thus begin a process that grows exponentially in a phenomenon called a chain reaction:ġ → 2 → 4 → 8 → 16 → 32 → 64 → 128 → 256 → 512 → 1,024 → 2,048 → 4,096 → 8,192 → 16,384 →…īecause energy is produced with each fission event, energy is also produced exponentially and in an uncontrolled fashion. These neutrons can themselves stimulate other uranium nuclei to undergo fission, releasing yet more energy and even more neutrons, which can in turn induce even more uranium fission. Notice that the fission of uranium produces two more free neutrons than were present to begin with. The two main components of the power plant are the nuclear reactor itself and the steam-driven turbine and electricity generator. \): A Diagram of a Nuclear Power Plant for Generating Electricity.
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