Luis Alvarez
Luis Alvarez was a Nobel Prize winning physicist, who is
probably most famous for the discovery of the iridium layer and his
theory that the mass extinction of dinosaurs was caused by an
asteroid or comet colliding with Earth. Besides doing the normal
work you might expect of a physics professor, Alvarez took on more
unusual projects, like making use of cosmic rays to search for
hidden chambers in an Egyptian pyramid.Early Life and EducationLuis
Walter Alvarez was born on June 13, 1911, in San Francisco,
California. His father, Walter Clement Alvarez, was a doctor who
wrote a large number of medical books. His mother was Harriet
Smyth.He began his education in San Francisco, first at Madison
School, then at San Francisco Polytechnic High School. In 1926,
when he was 15, his father changed jobs and the family moved to
Rochester, Minnesota. Luis Alvarez graduated from Rochester High
School, then started a Bachelor of Science course at the University
of Chicago in 1928, intending to major in chemistry.After a couple
of years, his grades in chemistry were not as good as he had hoped;
he was scoring B grades for his work, and he had also grown much
more interested in physics, so he decided to major in physics
instead. He graduated with a B.S. in physics in 1932, then
continued as a graduate student at Chicago, where he was awarded a
masters degree in 1934, and a Ph.D. in physics in 1936.Even at the
beginning of his time as a graduate student, Alvarez was at the
cutting-edge of physics. His doctoral advisor was Arthur Compton,
winner of the 1927 Nobel Prize in Physics for his discovery that
electromagnetic radiation, such as visible light, has particle-like
properties.In 1932, Alvarez built an array of Geiger counters that
he put to use studying cosmic rays. In 1933, using the data he had
gathered, he and Compton published a paper in thePhysical
Reviewestablishing that cosmic rays are positively charged
particles. Compton gave much of the credit for the work to his
young graduate student.After completing his Ph.D. in 1936, Alvarez
returned to his home state, beginning work as an experimental
physicist at the University of Californias Radiation Laboratory in
Berkeley. Luis Alvarezs Scientific AchievementsLuis Alvarez was a
highly talented and highly imaginative experimental physicist. He
had a particular talent for devising experiments that asked
questions in such a way that mother nature felt compelled to give a
good answer.Some of his achievements were:Establishing K-electron
captureOne way in which radioactive atoms transform themselves into
new elements is that their nuclei capture an orbiting electron. The
electron combines with a proton to form a neutron. The atom now has
one proton fewer than it used to, and so has become a new
element.This process had been predicted by theorists but never
observed until in 1937 Alvarez devised a new experiment. He would
look for the X-rays expected to be emitted by a nucleus after an
electron had been captured. Alvarezs experiment worked and
K-electron capture became an established phenomenon in physics.
If carbon-10 could undergo K-electron capture, the result would
be as shown above. A proton in the nucleus would capture an
electron and be converted to a neutron; the nucleus would become
boron-10. Luis Alvarez proved that K-electron capture was not just
another theory it actually happens.The CyclotronAlvarez spent a lot
of time at Berkeley working with the cyclotron (particle
accelerator/atom smasher). He was able to prove that helium-3 is
stable, although it had been predicted to be unstable.Air Safety
Improved by Ground-Controlled ApproachAlvarez was an enthusiastic
pilot; he learned to fly in 1933.In the early 1940s he invented the
Microwave Phased Array Antenna. This was a form of radar that gave
ground crew unparalleled precision in determining the position of
an aircraft in flight. The invention allowed ground crew to give
clear instructions to pilots as their aircraft approached runways
preparing to land.The system was particularly useful when
visibility was poor, such as in fog, or other adverse weather, or
when pilots were inexperienced. Alvarezs invention was used by the
military and civil authorities in various countries for decades,
greatly enhancing air safety.
Alvarezs ground-controlled approach radar allowed airplanes to
be talked down by air traffic controllers when visibility was
poor.Detecting Nuclear Weapons ProjectsIn 1943, during World War 2,
Alvarez was asked if it would be possible to detect if Germany had
its own atom bomb project. He knew that atom bomb research and
development produces radioactive gases, such as xenon-133. These
gases could be detected with the right equipment; and Alvarez was
an equipment expert. He decided the best way would be to fly
aircraft over Germany and try to detect these gases with radiation
detectors. The flights took place and found no evidence that
Germany had an atom bomb project. Alvarezs method was used after
the World War 2 to detect atomic research taking place around the
world.The Atomic BombIn 1944, Alvarez arrived at Los Alamos, New
Mexico, to work on the Manhattan Project. There he devised an
electrical detonation method for the plutonium bomb.He and his
graduate student Lawrence Johnston also designed equipment to
measure the energy released by a nuclear explosion.He and Johnston
flew as the scientists in an observation aircraft to Japan when the
bombs were dropped to measure how powerful the nuclear explosions
had been.
Luis Alvarez devised the first method for discovering if a
country is carrying out nuclear weapons research. He also devised
the first method of measuring how powerful a nuclear explosion has
been.The Hydrogen Bubble Chamber, Discovery of New Subatomic
Particles and the Nobel PrizeWhen the war was over, Luis Alvarez
moved back to Berkeley as a full professor. He was soon busy again
with experimental physics. It was becoming an exciting time to be
in particle physics, and the atom smashers at Berkeley made it an
ideal location for new discoveries.When he had begun university in
his late teens, only two fundamental particles had been known: the
proton and the electron. By 1932, the year he completed his degree,
the horizons of particle physics had widened greatly with the
discovery of two new particles: the neutron, discovered by James
Chadwick; and the positron, discovered byCarl Anderson.Further
discoveries K mesons and hyperons expanded the particle world in
the late 1940s, and by 1950 the pion family of particles had become
known.These discoveries relied on a device called the cloud
chamber, in which subatomic particles left vapor trails.One day in
1953 Alvarez got talking to a young physicist. The young man was
Donald Glaser. Over a meal at a conference, Glaser told Alverez
about his new invention the bubble chamber which was an improved
way of tracking subatomic particles. Glaser would go on to win the
1960 Nobel Prize for this invention.Alvarez thought about what
Glaser had told him. Glaser had used a bubble chamber filled with
liquid ether. Alvarez decided that a bubble chamber filled with
liquid hydrogen would be a perfect way of tracking particles coming
out of an accelerator. The idea was that the liquid hydrogen would
boil wherever a high energy particle passed through it, leaving a
trail whose path would allow the particles properties to be
calculated. By early 1954, Alvarez had put together a first,
small-scale liquid hydrogen bubble chamber at Berkeley.By 1956, a
large chamber was in operation. In the late 1950s this chamber was
used to discovery a variety of new particles and resonance states.
Alvarez was awarded the 1968 Nobel Prize in Physics for the work he
and his group had carried out. His prize award was: for his
decisive contributions to elementary particle physics, in
particular the discovery of a large number of resonance states,
made possible through his development of the technique of using
hydrogen bubble chamber and data analysis.
Fermilab image of tracks left by subatomic particles passing
through a bubble chamber. Physicists can figure out the properties
of particles by studying the trails they leave.Using Radiation from
Space to Search for Pyramid Chambers
The Pyramid of Chephren, with the Sphinx in the foreground.
Image: Hamish2k.In 1967, Alvarez had the ingenious idea that hidden
chambers in Egypts pyramids could be revealed by making use of
cosmic rays to take a X-ray type photo.He placed a cosmic ray
detector in an existing chamber below in the Pyramid of Chephren
the second largest of the Pyramids of Giza. The rate that cosmic
rays arrived at the detector would reveal any spaces within the
pyramids structure. Alvarez was able to study about one-fifth of
the pyramids volume, but found no new chambers.Dinosaur Death by
MeteoriteAlvarezs son Walter, like his father, had become a
scientist.Walter was a geologist, and one day in 1977 he decided to
tell his father about a problem he had. His problem was called the
K-T boundary, a gray colored layer of clay found in rocks.This clay
layer was unusual, because it was found all over the world, and it
was the same age everywhere, meaning the layer had been made all
over the world at exactly the same time 65 million years ago.And
even better, from Luiss perspective because he loved scientific
puzzles was the fact that below the layer you could find dinosaur
fossils in the rocks, but above the layer there were no dinosaur
fossils. Dinosaurs and many other lifeforms that existed before
this layer of clay was formed were extinct afterwards.This was not
a new problem. The boundary and the change of lifeforms on either
side of it had been noticed in Paris in the early 1800s by Georges
Cuvier, who had proposed that some catastrophic event had caused
the clay layer. However, Cuviers ideas became unpopular because the
new science of geology was governed by the uniformitarianism
doctrine the belief that all changes in the earths geology happen
gradually.
Luis and Walter Alvarez at the boundary layer marking a mass
extinction of life on Earth.After discussing the problem, father
and son started off with a rather modest goal.They wanted to
measure how long it took for the 1 centimeter deep layer Walter had
been investigating in Italy to form.Luis decided the best way to do
this would be to measure how much of the chemical element iridium
was present from the top through to the bottom of the layer.Iridium
in the earths crust comes mainly from meteorite impacts, and Luis
had calculated the average amount of iridium that arrives on Earth
each year from meteorites. Comparing iridium levels in the layer
with typical iridium arrival rates would tell him how long it took
for the layer to form.Luis asked Frank Asaro, a nuclear chemist at
the Lawrence Berkeley laboratory, to determine the iridium content
of samples of gray clay from the K-T boundary layer. Asaro and his
nuclear chemist colleague Helen Michel found much higher
concentrations of iridium in the samples than anyone could have
imagined, much more than could be explained by the normal number of
meteorite impacts.In 1980 the team published their evidence and
stated their belief that the K-T boundary layer and the mass
extinction event had been caused by a massive meteorite impact.Luis
Alvarez calculated a 10-kilometer-diameter meteorite traveling at
25 kilometers per second had hit Earth 65 million years ago. The
impact had sent a huge volume of rock dust into the atmosphere
which had eventually settled to form a thin gray layer all over the
world.While the dust was in the atmosphere it blocked the suns
rays, putting a stop to photosynthesis, and cooling the planet.
Without food and heat, the dinosaurs died out.
Very high levels of iridium in the K-T boundary lay suggested an
extra-terrestrial origin for the event that wiped out the
dinosaurs.Most paleontologists were unconvinced by Alvarezs
explanation of the mass-extinctions cause. It is fair to say that
the debate between paleontologists and supporters of the Alvarez
theory was fierce and raw. There was a large amount of ill-feeling
in the opposing camps, not helped, it must be said, by Luis Alvarez
himself. Alvarez was generally cantankerous and dismissive of
anyone with a view different to his own.I dont like to say bad
things about paleontologists, but theyre not very good scientists.
Theyre more like stamp collectors.LUIS ALVAREZ, 1911 1988In 1990,
two years after Luis Alvarezs death, the Chicxulub crater in the
sea off Mexicos Yucatan Peninsula came to the attention of
geologists, who agreed that the profile and age of the crater
matched the Alvarez predictions.The meteorite impact itself is no
longer a topic of debate. It is completely accepted that Alvarezs
team was right about this.Whether the mass extinction was caused
mainly or exclusively by the impact is, however, still
debated.There is an alternative theory that the extinction might
have been assisted or even wholly caused by another catastrophic
event, namely the enormously violent volcanic eruptions that took
place in the Deccan Traps in India in the same geologic time frame
as the meteorite impact.Someday, no doubt, the debate over the
cause(s) of the mass extinction will be settled, but it hasnt been
yet!The EndLuis Alvarez died of cancer of the esophagus at the age
of 77 on September 1, 1988. He was survived by his first wife
Geraldine Smithwick, and their children Walter and Jean; and his
second wife Janet Landis, and their children Donald and Helen.
