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Stellar Evolution
Now and again, strange things happen in the sky. Over time these strange
happenings were observed and noted down by astronomers and writers. Star-like
objects suddenly appeared in the sky, got brighter until some of them could be
seen in daylight and then slowly faded and disappeared. There are two famous
examples of these in the past millennium. On July 4th, 1054, Chinese astronomers
observed a new ‘guest star’ in the constellation Taurus. It grew brighter
until it was the brightest object in the sky after the Moon and could be seen in
daylight for three weeks. The astronomer Johannes Kepler observed a similar
event in 1604. Kepler wrote about the event in a book entitled ‘De Stella
Nova’ (About the New Star), from which derives the name: nova, or supernova.
What was observed in both events was the death of a star.
All stars begin their lives in clouds of dust and gas, mostly hydrogen and
helium in interstellar space, that collapse into clumps due to gravity. If
enough gas is accreted, gravity compresses the gases in the centre of the clump
until the compression and temperature ignites the fusion reactions that are the
source of every star’s energy.
The amount of gas going into the making of the star determines how long it will
live and how it will die. At one extreme is the ‘red dwarf’. Just large
enough to sustain a feeble fusion reaction at its core, its energy output is low
and shows up in telescopes as a dim red glow as its name implies. These
unimpressive stars are nevertheless the longest living due their low energy
consumption and can survive for over half the age of the universe itself. Some
neighbouring examples are Barnard’s Star about six light-years and Wolf 359
about eight light-years distant.
At the other extreme is the massive star, many times the Sun’s mass, which
lives fast and dies young. It burns its vast hydrogen reserves at prodigious
rates creating spectacular, unstable outputs of vast quantities of energy,
exhausting it in a few million years. Then, depending on its size, it continues
to convert helium to carbon, carbon to neon, neon to oxygen, oxygen to silicon,
and finally, silicon to iron, at ever increasing temperatures and decreasing
times. Finally, the fuel runs out and the star collapses under its gravity,
creating pressures and temperatures so high that the dying star is ripped apart
in a cataclysmic explosion, called a Type II Supernova. These stars leave
interesting legacies. The stars cores are compressed in the explosion creating
super-dense objects like neutron stars, as happened in the 1054 supernova,
located inside the Crab Nebula in Taurus—see image by Hubble Space telescope.
The expanding gases from the explosion seed the cosmos with elements forged
during the star’s lifetime, and during its death throes. These elements go on
to make new worlds- and new life. The atoms in our bodies were forged deep
inside a massive, dying star!
Clear skies!
Visit www.shannonsideastronomy.com
or call Conn on 061-301493.
This composite image was assembled from 24 individual exposures taken with the
NASA Hubble Space Telescope’s Wide Field and Planetary Camera 2 in October
1999, January 2000, and December 2000. It is one of the largest images taken by
Hubble and is the highest resolution image ever made of the entire Crab Nebula.
Credit: NASA, ESA, J.Hester and A. Loll (Arizona State University).
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