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Thursday, November 20, 2014

American Scientist Edwin Hubble- wikipedia

Edwin Hubble

From Wikipedia, the free encyclopedia
This article is about the astronomer. For the politician, see Edwin N. Hubbell. For the jazz trombonist, see Eddie Hubble.
Edwin Hubble
Edwin-hubble.jpg
Born Edwin Powell Hubble
November 20, 1889
Marshfield, Missouri
Died September 28, 1953 (aged 63)
San Marino, California
Residence United States
Nationality American
Fields Astronomy
Institutions University of Chicago
Mount Wilson Observatory
Alma mater University of Chicago
University of Oxford
Known for Hubble sequence
Influenced Allan Sandage
Notable awards Newcomb Cleveland Prize 1924
Bruce Medal 1938
Franklin Medal 1939
Gold Medal of the Royal Astronomical Society 1940
Legion of Merit 1946
Signature
Edwin Hubble (November 20, 1889 – September 28, 1953)[1] was an American astronomer who played a crucial role in establishing the field of extragalactic astronomy and is generally regarded as one of the most important observational cosmologists of the 20th century. Hubble is known for showing that the recessional velocity of a galaxy increases with its distance from the earth, implying the universe is expanding.[2] Known as "Hubble's law", this relation had been discovered previously by Georges Lemaître, a Belgian priest/astronomer who published his work in a less visible journal. There is still much controversy surrounding the issue,[3] and some argue that it should be referred to as "Lemaître's law", although this change has not taken hold in the astronomy community.
Edwin Hubble is also known for providing substantial evidence that many objects then classified as "nebulae" were actually galaxies beyond the Milky Way.[4] American astronomer Vesto Slipher provided the first evidence for this argument almost a decade before.[5][6]
Edwin Hubble supported the Doppler shift interpretation of the observed redshift that had been proposed earlier by Slipher, and that led to the theory of the metric expansion of space.[7][8] He tended to believe that the frequency of light could, by some so far unknown means, decrease the longer light travels through space.[9]

Biography

Edwin Hubble was born to Virginia Lee James (1864-1934)[10] and John Powell Hubble, an insurance executive, in Marshfield, Missouri, and moved to Wheaton, Illinois, in 1900.[11] In his younger days, he was noted more for his athletic prowess than his intellectual abilities, although he did earn good grades in every subject except for spelling. Edwin was a gifted athlete playing baseball, football, basketball, and he ran track in both high school and college.[12] He played a variety of positions on the basketball court from center to shooting guard. In fact Hubble even led the University of Chicago's basketball team to their first conference title in 1907.[12] He won seven first places and a third place in a single high school track and field meet in 1906. That year he also set the state high school record for the high jump in Illinois. Another of his personal interests was dry-fly fishing, and he practiced amateur boxing as well.[13]
His studies at the University of Chicago were concentrated on mathematics and astronomy, which led to a bachelor of science degree in 1910. Hubble also became a member of the Kappa Sigma Fraternity. He spent the three years at The Queen's College, Oxford after earning his bachelors as one of the university's first Rhodes Scholars, initially studying jurisprudence instead of science (as a promise to his dying father),[14] and later added literature and Spanish,[14] and earning his master's degree.[15]
In 1909, Hubble's father moved his family from Chicago to Shelbyville, Kentucky, so that the family could live in a small town, ultimately settling in nearby Louisville. His father died in the winter of 1913, while Edwin was still in England, and in the summer of 1913, Edwin returned to care for his mother, two sisters, and younger brother, as did his brother William. The family moved once more to Everett Avenue, in Louisville's Highlands neighborhood, to accommodate Edwin and William.[16]
Hubble was also a dutiful son, who despite his intense interest in astronomy since boyhood, surrendered to his father's request to study law, first at the University of Chicago and later at Oxford, though he managed to take a few math and science courses. After the death of his father in 1913, Edwin returned to the Midwest from Oxford, but did not have the motivation to practice law. So he taught Spanish, physics, and mathematics at the New Albany High School in New Albany, Indiana for a year before he resolved to start over, at the age of 25, to become a professional astronomer. He also coached the boys' basketball team there. After a year of high-school teaching, he entered graduate school with the help of his former professor from the University of Chicago to study astronomy at the Yerkes Observatory of the University, where he received his PhD in 1917. His dissertation was titled Photographic Investigations of Faint Nebulae.
When Congress declared war on Germany in 1917, Hubble rushed his dissertation for his PhD, volunteering for the United States Army and was assigned to the newly created 86th Division. He rose to the rank of Major and was found fit for overseas duty on July 9, 1918. The 86th Division never saw combat, and after the end of World War One Hubble spent a year in Cambridge, where he renewed his studies of Astronomy.[17] In 1919, Hubble was offered a staff position in California by George Ellery Hale, the founder and director of the Carnegie Institution's Mount Wilson Observatory, near Pasadena, California, where he remained on the staff until his death. Hubble also served in the U.S. Army at the Aberdeen Proving Ground during World War II. For his work there, he received the Legion of Merit award. Shortly before his death, Mount Palomar's giant 200-inch (5.1 m) reflector Hale Telescope was completed, and Hubble was the first astronomer to use it. Hubble continued his research at the Mount Wilson and Mount Palomar Observatories, where he remained active until his death.
Although Hubble was raised as a Christian, he later became an agnostic.[18][19]
Hubble experienced a heart attack in July 1949 while on vacation in Colorado. He was taken care of by his wife, Grace Hubble, and continued on a modified diet and work schedule. He died of cerebral thrombosis (a spontaneous blood clot in his brain) on September 28, 1953, in San Marino, California. No funeral was held for him, and his wife never revealed his burial site.[20][21][22]

Discoveries

The universe goes beyond the Milky Way galaxy

Edwin Hubble's arrival at Mount Wilson, California in 1919 coincided roughly with the completion of the 100-inch (2.5 m) Hooker Telescope, then the world's largest telescope. At that time, the prevailing view of the cosmos was that the universe consisted entirely of the Milky Way Galaxy. Using the Hooker Telescope at Mt. Wilson, Hubble identified Cepheid variables (a kind of star; see also standard candle) in several spiral nebulae, including the Andromeda Nebula and Triangulum. His observations, made in 1922–1923, proved conclusively that these nebulae were much too distant to be part of the Milky Way and were, in fact, entire galaxies outside our own. This idea had been opposed by many in the astronomy establishment of the time, in particular by the Harvard University-based Harlow Shapley. Despite the opposition, Hubble, then a thirty-five-year-old scientist, had his findings first published in The New York Times on November 23, 1924,[23] and then more formally presented in the form of a paper at the January 1, 1925 meeting of the American Astronomical Society.[24] Hubble's findings fundamentally changed the scientific view of the universe. Supporters of Hubble's expanding universe theory state that Hubble's discovery of nebulas outside of our galaxy helped pave the way for future astronomers.[25] Although some of his more renowned colleagues simply scoffed at Hubble's idea of an expanding universe, Hubble ended up publishing his findings on nebulas. This published work earned him an award titled the American Association Prize and five hundred dollars from Burton E. Livingston of the Committee on Awards.[12]
Hubble also devised the most commonly used system for classifying galaxies, grouping them according to their appearance in photographic images. He arranged the different groups of galaxies in what became known as the Hubble sequence.[26]

Redshift increases with distance

The 100-inch (2.5 m) Hooker telescope at Mount Wilson Observatory that Hubble used to measure galaxy distances and a value for the rate of expansion of the universe.
Combining his own measurements of galaxy distances based on Henrietta Swan Leavitt's period-luminosity relationship for Cepheids with Vesto Slipher and Milton L. Humason's measurements of the redshifts associated with the galaxies, he discovered a rough proportionality of the objects' distances with their red shifts.[2] Though there was considerable scatter (now known to be due to peculiar velocities), he was able to plot a trend line from the 46 galaxies and obtained a value for the Hubble Constant of 500 km/s/Mpc, which is much higher than the currently accepted value due to errors in their distance calibrations. In 1929 Hubble formulated the Redshift Distance Law, nowadays termed simply Hubble's law, which, if the redshift is understood to be a measure of recession velocity, is consistent with the solutions of Einstein's equations of general relativity for a homogeneous, isotropic expanding space. Although concepts underlying an expanding universe were well understood earlier, this statement by Hubble and Humason led to wider-scale acceptance for this view. The law states that the greater the distance between any two galaxies, the greater their relative speed of separation. But two years before, in 1927, Georges Lemaître, a Belgian Catholic priest and physicist, published a paper in an obscure Belgian journal, Annales de la Société Scientifique de Bruxelles. In that paper, he showed that the data collected by Hubble and two other astronomers up to that time was enough to derive a linear velocity-distance relation between the galaxies, and that this supported a model of an expanding universe based on Einstein's equations for General Relativity.
This discovery was the first observational support for the Big Bang theory which had been proposed by Georges Lemaître in 1927. The observed velocities of distant galaxies, taken together with the cosmological principle, appeared to show that the universe was expanding in a manner consistent with the Friedmann-Lemaître model of general relativity. In 1931 Hubble wrote a letter to the Dutch cosmologist Willem de Sitter expressing his opinion on the theoretical interpretation of the redshift-distance relation:[27]
Mr. Humason and I are both deeply sensible of your gracious appreciation of the papers on velocities and distances of nebulae. We use the term 'apparent' velocities to emphasize the empirical features of the correlation. The interpretation, we feel, should be left to you and the very few others who are competent to discuss the matter with authority.
Today, the "apparent velocities" in question are understood as an increase in proper distance that occurs due to the expansion of space. Light traveling through stretching space will experience a Hubble-type redshift, a mechanism different from the Doppler effect (although the two mechanisms become equivalent descriptions related by a coordinate transformation for nearby galaxies).
In the 1930s, Hubble was involved in determining the distribution of galaxies and spatial curvature. These data seemed to indicate that the universe was flat and homogeneous, but there was a deviation from flatness at large redshifts. According to Allan Sandage,
Hubble believed that his count data gave a more reasonable result concerning spatial curvature if the redshift correction was made assuming no recession. To the very end of his writings he maintained this position, favouring (or at the very least keeping open) the model where no true expansion exists, and therefore that the redshift "represents a hitherto unrecognized principle of nature."[28]
There were methodological problems with Hubble's survey technique that showed a deviation from flatness at large redshifts. In particular, the technique did not account for changes in luminosity of galaxies due to galaxy evolution. Earlier, in 1917, Albert Einstein had found that his newly developed theory of general relativity indicated that the universe must be either expanding or contracting. Unable to believe what his own equations were telling him, Einstein introduced a cosmological constant (a "fudge factor") to the equations to avoid this "problem". When Einstein learned of Hubble's redshifts, he immediately realized that the expansion predicted by General Relativity must be real, and in later life he said that changing his equations was "the biggest blunder of [his] life." In fact, Einstein apparently once visited Hubble and tried to convince him that the universe was expanding.[29]

Other discoveries

Hubble discovered the asteroid 1373 Cincinnati on August 30, 1935. He also wrote The Observational Approach to Cosmology and The Realm of the Nebulae approximately during this time.[30]

No Nobel Prize

Hubble spent much of the later part of his career attempting to have astronomy considered an area of physics, instead of being its own science. He did this largely so that astronomers—including himself—could be recognized by the Nobel Prize Committee for their valuable contributions to astrophysics. This campaign was unsuccessful in Hubble's lifetime, but shortly after his death, the Nobel Prize Committee decided that astronomical work would be eligible for the physics prize.[12] However, the prize is not one that can be awarded posthumously.

Stamp

On March 6, 2008, the United States Postal Service released a 41-cent stamp honoring Hubble on a sheet titled "American Scientists" designed by artist Victor Stabin.[21] His citation reads:
Often called a "pioneer of the distant stars," astronomer Edwin Hubble (1889–1953) played a pivotal role in deciphering the vast and complex nature of the universe. His meticulous studies of spiral nebulae proved the existence of galaxies other than our own Milky Way. Had he not died suddenly in 1953, Hubble would have won that year's Nobel Prize in Physics.
The other scientists on the "American Scientists" sheet include Gerty Cori, biochemist; Linus Pauling, chemist, and John Bardeen, physicist.

Honors

Awards
Named after him

In popular culture

The play "Creation's Birthday", written by Cornell physicist Hasan Padamsee, tells Hubble's life story.[31] A famous quote by Edwin Hubble goes: "Equipped with his five senses man explores the universe around him and calls the adventure science".[32]

See also

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