Transcript Lecture 39x

Origin of the
Elements
Cosmochemistry I
Lecture 39
Cosmochemistry
• Questions:
o When and how did the elements form?
• What is the universe composed of? Is it uniform in space and time?
o When and how did the solar system form?
• What is the solar system composed of?
o When and how did the Earth form?
• Sources of answers
o Laws of physics and chemistry
o Astronomical observations, including spectral (chemical) observations of
stars, including the Sun, and planetary objects
o Meteorites
o Lunar Samples
o Remote analyses from Martian landers
o Interplanetary dust and solar wind
Astronomical Background
•
•
•
•
•
•
•
Stars are classified based on their color (and
spectral absorption lines), which is in turn related to
their surface temperature.
On a plot of luminosity versus wavelength of their
principal emissions (color), called, most stars fall
along an array defining the “main sequence”.
Since wavelength is inversely related to the fourth
power of temperature, this correlation means that
hot stars give off more energy than cooler stars.
Mass is also related to temperature for main
sequence stars: hot stars are big, cool stars are
small.
The relationship between mass, luminosity, and
temperature is nonlinear. For example, an O star
that is 30 times as massive as the Sun will have a
surface temperature 7 times as hot and a luminosity
100,000 times brighter.
Stars on the main sequence produce energy by
“hydrogen burning”, fusion of hydrogen to produce
helium. The relationship results from the rate of
hydrogen burning: large stars have hot, dense
interiors and burn hydrogen much faster than
smaller stars.
Consequently there is an inverse relationship
between the main sequence lifetime of a star and
mass. The most massive stars, up to ~100 solar
masses, have life expectancies of only about 106
years, whereas small stars, ~0.01 solar masses,
remain on the main sequence for more than 1010
years.
Stars are also divided into Population I stars, greater
heavy element contents, and Population II stars,
small, metal-poor, occurring mainly in globular
clusters outside main galactic disk.
Hertzsprung-Russell diagram
In the beginning…
• The universe began
infinitely hot and
infinitesimally small 13.8
billion years ago in the Big
Bang.
• Since then the universe
has been expanding,
cooling, and evolving.
• Stars were born and stars
died.
• Galaxies formed and
merged.
Non-Main Sequence Stars
•
•
•
•
•
The two most important exceptions to the
main sequence stars, the red giants and
the white dwarfs, represent stars that have
burned all the H fuel in the cores and have
moved on in the evolutionary sequence.
H in the core is not replenished because the
density difference prevents convection
between the core and outer layers, which
are still H-rich. The interior part of the core
collapses under gravity until temperature
and pressure are great enough for He
burning to begin. At the same time the
exterior expands and cools, resulting in a
red giant, a star that is overluminous relative
to main sequence stars of the same color.
The fate of stars when the He in the core is
exhausted depends on their mass. Nuclear
reactions in small stars cease and they
simply contract, their exteriors heating up as
they do so, to become white dwarfs. Larger
stars go onto to ‘burn’ heavier elements in
their cores – we’ll talk about that later.
The other exceptions are the T-Tauri types
stars. These are young stars in which fusion
has not yet ignited. They are radiating the
energy of gravitational collapse.
Polygenetic hypothesis and
the origin of the elements
•
Our understanding of nucleosynthesis
comes from three sets of observations:
o
o
o
•
Two possibilities for formation of the
elements:
o
o
•
•
(1) the abundance of isotopes and elements in the
cosmos;
(2) experiments on nuclear reactions that determine
what reactions are possible (or probable) under
given conditions; and
(3) inferences about possible sites of nucleosynthesis
and about the conditions that prevail in those sites.
(1) they were formed in the Big Bang itself
(2) they were subsequently produced
Differences between old Population II
stars and younger Population I stars
suggests the universe has evolved.
However, no single mechanism could
be found to explain the observed
abundances of the elements.
B2FH and Nucleosynthesis
• Burbidge, Burbidge,
Fowler and Hoyle (1957)
proposed the elements
were created in 4
ways/environments:
o Cosmological nucleosynthesis:
creation in the Big Bang
o Stellar nucleosynthesis: synthesis
of elements by fusion in stars
o Explosive nucleosynthesis:
synthesis of elements by neutron
and proton capture reactions in
supernovae
o Galactic nucleosynthesis:
synthesis of elements by cosmic
ray spallation reactions
Margaret and Geoffrey Burbidge
Cosmological Nucleosynthesis
•
Immediately after the Big Bang, the universe
was too hot for any matter to exist.
o
•
•
•
•
•
•
But within a microsecond or so, it had cooled to 1011 K so
that matter began to condense.
At first electrons, positrons, and neutrinos
dominated, but as the universe cooled and
expanded, protons and neutrons became
more abundant. These existed in an
equilibrium dictated by the following reactions:
1 H + e– ⇄ n + ν
n + e+ ⇄ 1 H + ν
As temperatures cooled through 1010 K, the
reactions above progressively favored protons.
In less than two seconds things had cooled
enough so that these reactions ceased,
freezing in a 6 to 1 ratio of protons to neutrons.
It took another 100 seconds for the universe to
cool to 109 K, which is cool enough for 2H to
form:
1H + 1n ⇋ 2 H + γ
Subsequent reactions produced 3He, 4He and
a wee bit of Li.
Within 20 minutes or so, the universe cooled
below 3 x 108 K and nuclear reactions were no
longer possible.
Some 400,000 years later, the universe had
cooled to about 3000 K, cool enough for
electrons to be bound to nuclei, forming
atoms.
Stellar Nucleosynthesis
• When density of a forming star reaches 6 g/cm and T
reached 10 to 20 million K, hydrogen burning, or the pp
process, can begin which involves reactions such as:
1H + 1H → 2H + β+ + ν
2H + 1H → 3He + γ
3He + 3He → 4He + 21H + γ
• CNO cycle: carbon acts a nuclear catalyst to also
synthesize 4He from 1H
• 12C(p,γ) 13N(β++,γ) 13C(p, γ) 14N(p, γ) 15O(β+,ν) 15N(p,α)
12C
• limited to larger Pop. I stars
• These are the sources of energy sustaining main
sequence stars.
o Little synthesis beyond He; some minor production/consumption of light
nuclides, particularly in the CNO cycle.
Clarification: AFC equation
• Equation written as:
æ
∆ö
R
d m - d 0 = ç [d a - d 0 ] + ÷ {1- f - R/( R-1) }
è
ø
o is for R defined as the ratio of
mass assimilated to mass
crystallized (as shown in Figure).
• For R defined as mass
crystallized to mass
assimilated, the
equation should be
d m - d 0 = ([d a - d 0 ] + R ´ ∆ ) {1- f - R/( R-1) }
o (but this is not how the figure is
labeled).
Example: p, r, and s nuclides
Stellar Nucleosynthesis in Red Giants
•
Once the H is exhausted in the stellar core
the interior collapses, raising T and P.
o
o
o
o
•
•
•
The exterior expands and cools. This is the red giant
phase.
When T reaches 108 K and density reaches 104 g/cc in
the He core), He burning begins:
4He + 4He → 8Be + γ
8Be + 4He → 12C + γ
Because the t1/2 of 8Be is only 10-16 sec, 3He must collide
effectively simultaneously, which is why pressure must
be so high.
He burning also produces some O, 20Ne and 24Mg but Li,
Be, and B are skipped: they are not synthesized, rather
they are consumed in stars.
Once He is consumed in the core, low mass
stars such as the Sun cannot reach T and P
for heavier fusion reactions and they end
their lives as white dwarfs.
Stars bigger than about 4 M☼ undergo
further collapse and the initiation of carbon
burning when temperatures reach 600
million K and densities 5 x 105 g/cc.
For stars more massive than 11 M☼, about
1% of all stars, evolution now proceeds at
an exponentially increasing pace as
successive fusion reactions at higher T and
P.
Evolution of a 25 solar mass
star.
The e-process
•
•
•
As the finale approaches, the star has
become a cosmic onion of sorts, with layers of
heavier and heavier elements.
A new core consisting mainly of 28Si has been
created.
At temperatures near 109 K and densities
above 107 g/cc a process known as silicon
burning, or the e-process (for equilibrium).
o
•
•
•
This process is really a variety of reactions that can be
summarized as the photonuclear rearrangement of a gas
originally consisting of 28Si nuclei into one which consists
mainly of 56Ni, which then decays with a half-life of 6 days to
56Fe, the most stable of all nuclei.
The e-process includes reactions such as:
28Si + γ ⇄ 24Ne + 4He
28Si + 4He ⇄ 32S + γ
32S + 4He ⇄ 36Ar + γ
While these reactions can proceed in either
direction, there is a tendency for the build-up
of heavier nuclei with masses 32, 36, 40, 44, 48,
52, and 56, Partly as a result of the e-process,
these nuclei are unusually abundant in nature.
A variety of minor nuclei are produced as well.
This continues for a few days at most. Finally,
the inner core has been converted completely
to 56Ni and 56Fe, the latter the most stable of all
nuclei. Exogenic fusion reactions are no longer
possible.
In the meantime… The s-process
• In second and later generation stars containing heavy
elements, yet another nucleosynthetic process can
operate. This is the slow neutron capture or s-process. It
operates mainly in the red giant phase, during which
some fusion reaction produce free neutrons, e.g.:
13C + 4He → 16O + n
•
• These neutrons are captured by nuclei to produce
successively heavier elements.
• The rate of production and the rate of capture,
however, is slow. Consequently, a radioactive isotope of
an element will decay before it can capture a second
neutron and gaps between isotopes of an element
cannot be bridged. This is the main difference between
this and the r-process.
Explosive Nucleosynthesis
•
•
•
•
•
•
Once the stellar core has been largely converted
to Fe, a critical phase is reached: the balance
between thermal expansion and gravitational
collapse is broken. The stage is now set for the
catastrophic death of the star: a supernova
explosion, the ultimate fate of stars with masses
greater than about 8 solar masses.
The energy released in the supernova is astounding.
In its first 10 seconds, the 1987A supernova released
more energy than the entire visible universe, and
100 times more energy than the Sun will release in its
entire 10 billion year lifetime.
The supernova begins with the collapse of the
stellar core, which would have a radius similar to
the Earth’s radius before collapse, collapsing to a
radius of 100 km or so in a few tenths of a second.
When matter in the center of the core is
compressed beyond the density of nuclear matter
(3 ´ 1014 g/cc), it rebounds, sending a massive shock
wave back out. As the shock wave travels outward
through the core, the temperature increase
resulting from the compression produces a
breakdown of nuclei by photodisintegration, for
example:
56Fe + γ → 13 4He + 4 1n;
4He + γ 2 1H + 2 1n
This photodisintegration produces a large number
of free neutrons (and protons), which leads to
another important nucleosynthetic process, the rprocess.
The r- & p-processes
•
•
•
•
•
Because the abundance of neutrons is
exceedingly high, nuclei capture them at a
rapid rate – so rapid that even an unstable
nucleus will capture a neutron before it has
an opportunity to decay. The result is a
build-up of neutron-rich unstable nuclei.
Eventually the nuclei capture enough
neutrons that they are not stable even for a
small fraction of a second. At that point,
they undergoβ- decay to new nuclides,
which are more stable and capable of
capturing more neutrons.
This is the principal mechanism for building
up the heavier nuclei.
It reaches a limit when nuclei beyond A ≈
90 are reached. These heavy nuclei fission
into several lighter fragments.
The r-process is thought to have a duration
of 1 to 100 sec during the peak of the
supernova explosion.
The r-process tends to form the heavier
(neutron-rich) isotopes of a given element.
Proton capture, or the p-process, also
occurs in supernovae. The probability of
proton capture is much less than that of
neutron capture, so it is significant only for
the production of the lightest isotopes of a
given element.
r- s- and -processes summary
•
•
•
•
•
Shielding: If an isotope with z protons and n
neutrons has a stable isobar with n + x neutrons
and p - x protons, this isotope is shielded from
production by the r-process because b-decay
will cease when that stable isobar is reached.
S-process path is zig-zag: there is a zag every
time there is a non-stable isotope of an element:
in that case, the path zags to the next higher
atomic number element.
The least abundant are those created by only
one, particularly by only the p-process. These
tend to be both r-process shielded and off the sprocess path to low N (to the left).
The most abundant isotopes of an element tend
to be those created by all processes
The exact abundance of an isotope depends on
a number of factors, including its neutroncapture cross-section and the neutron-capture
cross-section and stability of neighboring nuclei.
The neutron-capture cross-section of a nuclide is
a measure of the affinity of that nuclide for
neutrons, i.e., a measure of the probability of
that nuclide capturing a neutron in a given
neutron flux.
Galactic Nucleosynthesis
•
•
•
•
Except for production of 7Li in the
Big Bang, Li, Be, and B are not
produced in any of the above
situations.
One clue to the creation of these
elements is their abundance in
galactic cosmic rays: they are
overabundant by a factor of 106.
They are believed to be formed
by interactions of cosmic rays
with interstellar gas and dust,
primarily reactions of 1H and 4He
with carbon, nitrogen, and
oxygen nuclei.
These reactions occur at high
energies (higher than the Big
Bang and stellar interiors), but at
low temperatures where the Li, B
and Be can survive.