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Atomic Nucleus
Atomic nucleus
The center of an
atom
is called the nucleus. It is composed of one or more
protons and usually some
neutrons as well. The number of protons in an atom's nucleus is called the
atomic number, and determines which
element the atom is (for example
hydrogen,
carbon,
oxygen, etc.).
Though the positively charged protons exert a repulsive
electromagnetic force on each other, the distances between
nuclear particles are small enough that the
strong interaction (which is stronger than the electromagnetic force but
decreases more rapidly with distance) predominates. (The
gravitational attraction is negligible, being a factor 1036
weaker than this electromagnetic repulsion.)
The discovery of the
electron was the first indication that the atom had internal structure. This
structure was initially imagined according to the "raisin cookie" or
"plum pudding" model, in which the small, negatively charged electrons were
embedded in a large sphere containing all the positive charge.
Ernest_Rutherford and Marsden, however,
discovered in 1911 that
alpha particles from a radium source were sometimes scattered backwards from
a gold foil, which led to the acceptance of a planetary model, in which the
electrons orbited a tiny nucleus in the same way that the planets orbit the sun.
A heavy nucleus can contain hundreds of nucleons (neutrons
and protons), which means that to some approximation it can be treated as a
classical system, rather than a
quantum-mechanical one. In the resulting
liquid-drop model, the nucleus has an energy which arises partly from
surface tension and partly from electrical repulsion of the protons. The
liquid-drop model is able to reproduce many features of nuclei, including the
general trend of
binding energy with respect to
mass number, as well as the phenomenon of
nuclear fission.
Superimposed on this classical picture, however, are
quantum-mechanical effects, which can be described using the
nuclear shell model, developed in large part by
Maria Goeppert-Mayer. Nuclei with certain numbers of neutrons and protons
(the magic numbers 2, 8, 20, 50, 82, 126, ...) are particularly stable, because
their shells are filled.
Since some nuclei are more stable than others, it follows
that energy can be released by nuclear reactions. The sun is powered by
nuclear fusion, in which two nuclei collide and merge to form a larger
nucleus. The opposite process is fission, which powers nuclear power plants.
Because the binding energy per nucleon is at a maximum for medium-mass nuclei
(around
iron),
energy is released either by fusing light nuclei or by fissioning heavier ones.
The elements up to iron are created in a star during a series
of fusion stages. First hydrogen fuses with itself to form helium, then helium
fuses with itself twice to make carbon, and further fusings proceed to make
heavier elements, until the series of fusions make iron which will not fuse
further. If the star explodes in a
supernova, the high energy neutrinos streaming from the supernova will
bombard the escaping elements to form substantial portions of the elemental
neuclei heavier than iron. Hence, during
stellar evolution through the progression of stages in fusing succeedingly
heavier elements, the death of a star in a supernova can create the elements
necessary for life.
Nuclear reactions occur naturally on earth. Except in manmade
conditions, such as atomic explosions, temperatures and pressures on earth are
not high enough to overcome the electrical repulsion between nuclei and allow
fusion. But heavy nuclei such as
uranium may undergo fission and
alpha decay, and
beta decay can also occur. Alpha decay can be considered as an extremely
asymmetric case of fission, in which one fragment is a helium nucleus (alpha
particle). In beta decay, either a proton is converted into a neutron (with
the emission of an antielectron and a neutrino) or a neutron is converted into a
proton (emitting an electron and an antineutrino).
Much of current research in
nuclear physics relates to the study of nuclei under extreme conditions. The
heaviest of all
nuclei are
neutron stars. Nuclei may also be characterized by extreme shapes (like
footballs) or by extreme neutron-to-proton ratios. Experimenters can also use
artificially induced fusion at high energies to create nuclei at very high
temperatures, and there are signs that these experiments have produced a
phase transition from normal nuclear matter to a new state, the
quark-gluon plasma, in which the
quarks mingle with one another, rather than being segregated in triplets as
neutrons and protons.
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