РефератыИностранный языкStStars Essay Research Paper Star BirthOur lives

Stars Essay Research Paper Star BirthOur lives

Stars Essay, Research Paper


Star Birth


Our lives are intimately linked to the stars, but in ways much more down to


earth than the romantic views of them. As we all know, our sun is a star and the


thermonuclear reactions that are continuously taking place inside it are what


provide and sustain life on our planet. What do we get from the sun? We get


carbon, oxygen, calcium and iron, courtesy of stars that disappeared billions of


years ago (Naeye, 1998). Star formation is a study in contradictions because the


formation of a star begins with atoms and molecules floating freely through space


that are brought together through gravity to form masses that become stars. Stars


go through three major stages of development in their transformation from infancy


to adult stars: a collection of dust and gases, protostar, full-blown star. Pictures of


these various stages are mind-boggling in their beauty and bring one to an


immense sense of awe at the machinations of the universe. Scientists believe that


stars begin as a collection of interstellar dust and gases (Frank, 1996). This mass of


dust and gases forms a cloud that begins shrinking and rotating until it eventually


develops into what is called a protostar. Once the protostar reaches sufficient


mass, it then begins the process of converting hydrogen to helium through a series


of nuclear reactions, or nuclear fusion until it becomes a full-blown star


(Astronomy, 1995). Those protostars that are too small to complete the nuclear


fusion die out to become what are known as brown dwarfs (refer to photo at right).


Thanks to an image from the Mt. Palomar observatory, astronomers have obtained


the first image of a brown dwarf, named Gliese 229B (or GL229B). It is a small


companion to the red star, Gliese 229, which is approximately 19 light-years from


Earth in the constellation Lepus. GL229B is too hot and massive to be classified as


a planet, yet at the same time it is too small and cool to be able to shine like a


typical star ?in fact, it is actually at least 100,000 times dimmer than our own sun


and is the faintest object ever to be discovered orbiting another star.


As a star forms, it is this ?fusion-powered heat and radiation? emanating from the


core of the star which keeps the star whole (Watery Nurseries, 1997). If it weren?t


for this, the star would actually collapse under the stress of its own weight.


However there is a balancing act that takes place within the star between radiation


and gravity (which provides fuel for the star) that prevents this and makes it


possible for star to have a life span of billions of years. The big question, though,


is how does this whole process get started and what actually makes it


possible for these masses meld together to form a star, instead of just exploding


back into cosmic particles? What actually happens is that the clouds of gas and


dust are actually drawn into compaction through self-created gravitational collapse.


As the picture at left (from the Hubble Telescope) shows, these clouds go through


continuous implosion to become solid masses. Scientifically speaking, it is logical


to assume that this implosion should actually generate so much heat that the gas


and dust expand, rather than come together and yet this is not the case.


The reason why, scientists believe, is due to water molecules that are formed


during this process. It is the addition of these charged molecules, called


hydronium, that they believe provide the ingredient necessary to prevent further


expansion of the gasses and dust, thereby allowing the continuance of implosion


until the star finally forms a solid mass. Hydronium is made up of three hydrogen


atoms and one oxygen ion. In theory, it has the ability to transform into water


(H2O) plus one independent hydrogen atom, as long as it is able to capture a free-


floating electron from somewhere. It takes hundreds of millions of years for the


particles of dust and gas to come together into these gigantic clouds that can span


hundreds of light-years in size. The clouds are dominated by their two prime


elements of hydrogen and helium while particles of dust make up about one


percent of a cloud?s mass. In addition, there are other molecules present that


contribute to the molecular structure of the cloud, such as ammonia and other


carbon-based elements. Each cloud contains enough elements to create


approximately ten thousand new stars. It takes many millennia for a collapsing gas


cloud to fragment into thousands of dense, rotating clumps of gas that will


eventually become newborn stars. The cores of these gaseous clumps are


continuously compacting more and more as their rotation becomes faster and faster


and, over time, the cores become elongated. Some of these elongated cores are


hypothesized to eventually become binary and multiple star systems by virtue of


the fact that the cloud is stretched out so mu

ch. Over time, stars naturally change.


Once the star enters its maturity, a stage where nuclear reactions begin to stabilize,


it will spend the majority of its existence there. As they age and enter the late


evolution stage, they often swell and become red giants which can evolve into


novas, planetary nebulas, or supernovas. By the end of its life, a star will change


into a white dwarf, black dwarf, or neutron star depending upon the composition of


its original stellar mass. Thanks to NASA’s Hubble Space Telescope we have


gained new insight into how stars might have formed many billions of years ago in


the early universe. This picture from the Hubble shows a pair of star clusters,


which might be linked through stellar evolution processes. There are actually a


pair of star clusters in this picture which are located approximately 166,000 light-


years from the Large Magellanic Cloud (LMC) in the southern constellation


Doradus. According to astronomers, the clusters, for being so distinctly separate,


are unusually close together. In the past, observations such as this were restricted


to clusters within our own Milky Way galaxy. Because of the fact that the stars in


the Large Magellaniv Cloud do not have many heavy elements in their


composition, they are considered to be much more primordial than other newly


forming stars and, therefore, more like scientists speculate stars were like in the


early universe. There is an ongoing debate among astronomers as to the


importance of disks in the formation process. Many astronomers believe that most


of the matter that makes up the star actually starts off inside a disk which spirals


inward until it coheres into a star. There have actually been observations of


massive disks as they orbit infant stars and it is these observations which have


led scientists to believe that disk accretion is very important to the process of star


formation. The key to understanding star formation is the correlation between


young stars and clouds of gas and dust. Usually the youngest group of stars have


large clouds of gas illuminated by the hottest and brightest of the new stars. The


old theory of gravity predicts that the combined gravitational attraction of the


atoms in a cloud of gas will squeeze the cloud, pulling every atom toward the


center. Then, we might expect that every cloud would eventually collapse and


become a star; however, the heat in the cloud resists collapse. Most clouds do not


appear to be gravitationally unstable, but such a cloud colliding with a shock wave


can be compressed disrupted into fragments. Theoretical calculations show that


some of these fragments can become dense enough to collapse and form stars.


Astronomers have found a number of giant molecular clouds where stars are


forming in a repeating cycle. Both high-mass and low -mass stars form in such a


cloud, but when the massive stars form, their intense radiation or eventual


supernova explosion push back the surrounding gas and compressive period. This


compression in turn can trigger the formation of more stars, some of which will be


massive. Thus a few massive stars can drive a continuing cycle a star formation


in a giant molecular cloud. While low-mass stars do form in such clouds along


with massive stars, low-mass stars also form in smaller clouds of gas and dust.


Because lower mass stars have lower luminosities and do not develop quickly into


supernova explosions, low-mass stars alone can not drive a continuing cycle a star


formation. Collapsing clouds of gases do not form a single object; because of


instabilities, it fragments producing an association of ten to a thousand stars. The


association drifts apart within a few million years. The sun probably formed in


such a cluster about five billion years ago. Stars are supported by the outward flow


Of energy generated by nuclear fusion in their interiors. The energy generated


Keeps each layer of the star hot enough so that the gas pressure can support the


weight of the layers above. Each layer in the star must be in hydrostatic


equilibrium; that is, the inward weight is balanced by outward pressure. Stars are


elegant in their simplicity. Nothing more than a cloud of gas held together by


gravity and warmed by nuclear fusion, a star can achieve stability balancing its


weight generating nuclear energy.


Astronomy: The Stars: The New York Public Library Science Desk


Reference, 01-01-1995.


Frank, Adam, In the nursery of the stars: infant stars are anything but quiet. They


kick, they scream, they spew forth a thousand suns’ worth of hot gas many light-


years into space.(Cover Story)., Vol. 17, Discover Magazine, 02-01-1996, pp 38.


Naeye, Robert, The story of starbirth. (origins of the universe)., Astronomy, Feb


1998 v26 n2 p50.


Watery stellar nurseries.(water may help stars form from gas clouds)., Vol. 18,


Discover Magazine, 07-01-1997, pp 14.

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