Apakah itu Kosmologi?
Untuk menjawab soalan apakah itu kosmologi, pertama kita harus definiskan terlebih dahulu kata kosmologi itu sendiri. Kata ini berasal dari bahasa Yunani: 'Cosmologia' (aturan, keberaturan, susunan, ornamen) + 'logos' (kata, penalaran, rancangan). Kosmologi adalah studi tentang alam semesta ini secara keseluruhan. Kajian Alam semesta ini mempunyai sejarah yang panjang, melibatkan setidaknya tiga wilayah: agama, filsafat, dan sains. Artikel berikut hanya berkonsentrasi pada kosmologi saintifik (ilmiah).
Scientific Cosmology
Also called physical cosmology, it is the branch of science that
deals with the scientific study of the origins and evolution of the
Universe and the nature of the Universe on its very largest scales.
In its earliest form physical cosmology was basically just
celestial mechanics, the study of the 'heavens'. The Greek philosophers
Aristarchus of Samos, Aristotle and Ptolemy proposed different theories
for how the heavens work.
In particular, the 'earth-centric' Ptolemaic system with it's perfect
circles and small 'epicycles' was the accepted theory to explain the
motion of the heavenly bodies. In the picture above, the Earth is at the
centre with the Sun, Moon and planets all revolving around Earth.
It was the best theory until Copernicus, Kepler and Galileo proposed a
'sun-centric' system in the 16th century. Although Greek, Indian and
Muslim savants formulated the sun-centric theory centuries before
Copernicus, his reiteration that the Sun, rather than the Earth, is at
the center of the solar system is considered among the most important
landmarks in the history of modern astronomy.
Newton's Cosmology
With Isaac Newton's 1687 publication of 'Principia Mathematica', the
problem of the motion of the heavenly bodies was solved. Newton provided
a physical mechanism for Kepler's laws of planetary motion. His law of
universal gravitation resolved the anomalies caused by gravitational
interaction between the planets in the previous systems.
Despite the words 'universal gravitation', Newton did not
consider the implications of his theory on the Universe at large,
although it implied that gravity works the same everywhere. The
universal application of gravity was left to Albert Einstein, who
formulated it more than two centuries later.
Heber D. Curtis, on the other hand, suggested that the observed
spiral nebulae were star systems in their own right, or 'island
universes'. In 1923-24 Edwin Hubble detected novae in the Andromeda
galaxy and then showed its distance to be way beyond the Milky Way's
boundaries. This settled the debate and it was accepted that the Milky
Way was not all the universe there is. However, the cosmos was still
thought to be static and unchanging.
Modern Cosmology
Subsequent modeling of the universe explored the possibility that
the cosmological constant introduced by Einstein may result in an
expanding universe, depending on its value. In 1929, Edwin Hubble's
discovered the red shift of the light of distant galaxies, indicating
that they move away from the Milky Way. Hence, the universe must be
expanding.
Einstein's Cosmology
Scientific cosmology really began in 1917, when Albert Einstein's
published the final modification to his theory of gravity in the paper
'Cosmological Considerations of the General Theory of Relativity'. This
paper prompted early cosmologists such as Willem de Sitter, Karl
Schwarzschild and Arthur Eddington to explore the astronomical
consequences of the theory of relativity.
Mount Wilson astronomer Harlow Shapley championed the model of a
cosmos made up of the Milky Way star system only – a static unchanging
universe. Einstein also believed this and 'fudged' his equations of
general relativity to represent this static state. He introduced a
'cosmological constant' that prevented the universe from contracting or
expanding, which was what his original equations told him.
Einstein promptly repudiated his earlier 'fudge factor' and declared
that the introduction of the cosmological constant was the "biggest
blunder of his scientific career". His original 1917 equations support
an expanding universe without the cosmological constant anyway.
In 1931 Georges Lemaitre, a Belgian priest, postulated that an
expanding universe meant a creation event at some time in the past. He
postulated that the Universe was created from a small 'cosmic egg' and
set to expand until today. This theory was later labeled the 'big bang'.
There were many rival theories to the big bang. The 1964
discovery of the cosmic microwave background radiation by Arno Penzias
and Robert Woodrow Wilson was a first step in ruling out many
alternative physical cosmologies.
The Golden Age of Cosmology
Recent observations made by the COBE and WMAP satellites
observing and accurately measuring this background radiation have
effectively, transformed cosmology from a highly speculative science
into a predictive science. This has led many to refer to modern times as
the "golden age of cosmology".
Present observations match predictions made by a theory called
Cosmic Inflation, first proposed by American physicist and cosmologist
Alan Guth in 1981. It is a modification of the standard big bang theory
that explains how the universe obtained the expansion and solves some
problem areas of the big bang satisfactorily.
Since there are still problems with scientifically explaining how
the universe came forth 'out of nothing', modern research are mainly
concentrated on 'quantum cosmology'. This is a branch of 'quantum
gravity', which strives to reconcile general relativity with quantum
physics. No satisfactory reconciliation has been possible yet.
Read more on Quantum Cosmology by clicking => Here
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