Hank Kosmata: The trail of discovery and development
leading to the design and construction of B Reactor at Hanford begins in the last decade
of 1800. We begin with the atom, a word that comes
from the Greek atomos, meaning “indivisible.” Until that time, it was believed that all
matter, everything in our universe, was composed of these indivisible particles. It was understood that the atoms of different
materials were unique, and up to that time about 70 different atoms or elements had been
discovered. But there was beginning to be a belief that
maybe the atom did have more than one part. Finally, in fact, in 1897, Joseph John Thompson,
an English physicist, discovered what was eventually called an electron. He identified it as part of an atom. He proved that it was much smaller than the
smallest atom, hydrogen, by a factor of almost 2,000, and that it had a negative electrical
charge. He believed it orbited around the rest of
the atom, now called the nucleus, like the earth around the sun. So as we entered the 20th century with respect
to experimental physics, that was the state of our knowledge of atoms. Science moves ahead both in theory and in
experiments. In 1905, a theoretical physicist was having
what would later be called his miracle year. A young German, Albert Einstein, had a new
PhD, was brilliant in math and physics, but so-so in other subjects. He had failed to get the teaching job he’d
hoped for and had to settle for a position as a patent clerk in Bern, Switzerland. His work there did give him time to think
about the world around him. He developed and published five of his famous
theories that year, one of which would have great significance to our story. This was his proof to the satisfaction of
his peers that energy and mass were related, and that every bit of matter, every atom,
contained energy. The relationship between the two was his famous
formula, E=mc2, where E, energy, is equal to m, mass, multiplied by the speed of light,
c—an enormous number—squared, which is a super enormous number. What it meant was that a kilogram, 2.2 pounds
of matter, any matter, contains an enormous amount of energy locked up in its atoms. How much? Well, 25 billion kilowatt hours of energy. That’s equal to the electrical energy output
of a large power reactor operating for three years. That’s a year’s supply of electrical energy
for 1.6 million households. How do you release that energy? Well, at that time, no one, including Dr.
Einstein, had any idea. His formula just said, if mass disappeared,
it would be replaced by energy. Moving back into the laboratory, now that
scientists understood the existence of electrons, they found ways to strip them away from atoms,
leaving a positive-charged nucleus, which they called an ion. The helium ion was determined to be identical
to a part of radiation given off by radium, and was given the name the “alpha particle”
by Ernest Rutherford, working at Cambridge in 1917. He used alpha particles to bombard nitrogen
atoms, which resulted in two very important discoveries. First, he was able to cause the nitrogen to
change or transform into oxygen. Second, when this happened, another particle
was released, which had about the mass of a hydrogen atom and was positively charged. He named this particle the “proton." Now, the atom was understood to have at least
three parts: electrons and protons in addition to the remaining nucleus. The search for the mystery of what might be
left in a nucleus began. In 1932, James Chadwick, also working at Cambridge,
discovered another particle which had the same mass as a proton, but was without any
electrical charge. It was a neutral particle, and he gave it
the name a “neutron.” Now, the atom could be characterized as having
neutrons and protons in its nucleus, and electrons spinning around the nucleus. The discovery of the neutron was a yet unrealized
world-changing event. At this point in our history, we meet a vital
key player, Dr. Enrico Fermi, an Italian physics professor. He had an interest, like many other physicists
at the time, in trying to transform atoms by bombarding them with subatomic particles. But he recognized that the neutron could be
a superior particle to use, since having no electrical charge, it could not be repelled
by the positive charge of the nucleus of the target atoms. He and his team, using a neutron-generating
chemical reaction of their invention, began bombarding atoms of different elements. In many cases, they were successful in creating
new isotopes. In each case, the new atom was an isotope
of the next heavier element in line in the periodic chart, with respect to the target
atom. Along the way, by accident—as often happens
in experimental science—they discovered that they got better results when their experiment
was done on a wood laboratory tabletop, as compared to a marble tabletop. They concluded that the neutrons were bouncing
off the light hydrogen atoms in the wood and were being slowed down before they reached
the target, which seemed to make them more easily absorbed by the target. They said the neutrons had been moderated. They decided to intentionally do this by placing
a block of paraffin, which is carbon and hydrogen, between the neutron generator and the target
atoms, and were rewarded with even greater success. They proceeded through the periodic table
of atoms until they reached the heaviest, uranium. Here they got a reaction, but they were unable
to identify the end product. At this point, they published their results
and this led to a Nobel Prize for Fermi. The 1938 Prize was for the discovery of new
isotopes by irradiation with slow neutrons. Fermi’s wife was Jewish. Seeing the terrible things beginning to happen
to Jews in Germany and Italy, he convinced the Italian government it would be a great
honor if his whole family would accompany them to receive this Nobel Prize. They packed as if for a short trip. But after receiving the prize, they sailed
for the United States, joining a large number of other scientists from Europe who were fleeing
for the same reason, including Albert Einstein, who was already gone to the U.S. The path of our history now moves to Germany,
where a PhD chemist, Otto Hahn, and a PhD physicist, Lise Meitner, with a 30-year working
relationship have now begun to investigate the Fermi experiments with slow neutrons and
uranium. Before they can conclude this work, Lise,
as a Jew, finds it necessary in the summer of 1938 to flee to Sweden. They continued to correspond. In a letter in late December of that year,
Hahn tells Lisa that when he and his new partner bombard uranium, they encounter the same puzzle
that confronted Fermi. What is the final product? Hahn is convinced that one thing left behind
seems to be the element barium. It turns out that when she receives this letter,
Lise’s nephew, Otto Frisch, who is a respected physicist working in Denmark, is visiting
Lise in Sweden. The two of them begin to ponder the puzzle
in a very interesting setting for what will be a world-changing event. They carry on their discussion of this problem
as they walk through a light snowfall, and finally sit on a fallen log and start to make
some calculations on scratch paper from their pockets. Lise insists that if Hahn sees barium, it
must be true, because she knows him to be a careful and superior chemist. They then make the scientific jump that no
one has ever made before—except for another lady we’ll meet later—and they conclude
that possibly the uranium atom has broken into parts. If it broke into two parts, just counting
the protons, if one part was barium, then likely the other part would be krypton, which
is a gas and could easily escape detection if one were not looking for it. Then Lise calculates that if these were the
two elements left behind, the combined atomic weight of the two would be very slightly less
than the parent uranium atom. They then realized if this slight amount of
matter had disappeared, there should have been an energy release, according to the Einstein
mass and energy formula. Frisch returned to Copenhagen, where he worked
under the world-famous physicist, Niels Bohr. When told of the conclusion of Frisch and
Meitner, Bohr is reported to have smacked himself on the forehead and shouted, “Of
course! Why haven’t seen this?” As it turns out, Bohr is leaving for the United
States on January 7th, 1939, for a series of physics conferences. He advises Frisch to make his own independent
experiments to confirm the reactions, and for Frisch and Meitner to publish a paper
describing their analysis. Frisch hurries to do these things. In the process, he asks a biologist friend
what they call the process of cell division. Told that it’s called binary fission, he
and Meitner decide to call the uranium split “fission.” When Bohr reaches New York, he is met by a
number of immigrant scientists, including Dr. Fermi. Soon, word of nuclear fission begins to spread
through the American scientific community, and many of them rush to their labs to verify
the process. It’s also at this time, they begin to realize
the dark side of this discovery, the potential for the release of enormous amounts of energy
and the possibility of what would later be called “atomic bombs.” There is also the concern that these experiments
began in Germany. The immigrant scientists know that many brilliant
and talented scientists are still in Germany and other European countries, because they
studied and worked with them or under them. Having seen firsthand what was happening in
Europe, the immigrant scientists began a two-phase campaign: 1) to find some way to shroud further
experiments and developments from the outside world, and 2) to find some way to warn the
American government of the potential consequences of the discovery, and to urge an all-out program
for America to be first in future developments. They needed to warn the president. Imagine the problem of a number of foreign
scientists, many with heavy accents, trying to explain to anyone in the government, including
the president, that the little-known element uranium has the potential to destroy a city. They decided they needed a well-known spokesman,
someone trusted by the president, who could carry the spokesman’s message. Since Albert Einstein was by far the best-known
scientist now in America and several of them had worked and studied with him in Europe,
they recruited him to be their spokesman. Two men, Leo Szilard and Eugene Wigner—men
who will continue to play significant parts in our history—composed a letter, which
Einstein signed. They found in their community a trusted non-scientist,
who was a good friend of the president, to carry their letter and to assure the president
that this letter, and these people, should be taken very seriously. The letter, delivered in September of 1939,
worked to the extent that President Roosevelt started the action to financially support
a focused research program to begin in this country. Now, we look at one of great “What-ifs?”
in our world history. Back in 1934, when Fermi was puzzled about
his results when he bombarded uranium with slow neutrons, a well-respected PhD German
chemist, Ida Noddak, wrote and published a paper and sent a copy to Professor Fermi,
suggesting that instead of looking for a larger element than uranium to be the product of
his experiments, possibly he should consider that the atom had broken into smaller parts,
and that he should look in that direction. For reasons never fully explained, he ignored
her. And more importantly, her fellow German scientists
ignored her. What if someone in Germany had seriously followed
up on her suggestion in 1934? What if they had done the Hahn/Meitner experiments
at that time and arrived at Meitner’s explanation before she was chased out of Germany? What if the German government had begun to
secretly explore nuclear fission in 1934? This is the same government that developed
jet engines and long-range rockets by 1944. Imagine, at least a five-year head-start on
the rest of the world in the pursuit of nuclear weapons. It’s a chilly thought. Back to the experimental history. S very important discovery in several labs
in 1939 revealed that when the uranium atom fissions, it releases two to three new neutrons. If one neutron can cause a release of two
to three neutrons, and if those two to three can each cause the release of another two
to three, then it was possible that what was called a chain reaction could occur. Since these reactions would occur in a tiny
fraction of a second, and since each fission also released significant amounts of energy,
this led further to the possibilities of a nuclear weapon. Another significant discovery occurred in
1940. It was determined that the uranium atom that
fissioned was not the base uranium-238 atom, but rather a uranium-235 isotope. Uranium-235 is only .7% of natural uranium. The government program considering the use
of uranium as a fission weapon now had to refocus on the uranium-235 isotope, and how
to separate it from the base natural uranium. Since isotopes are identical chemically, they
can only be separated by some physical process, such as centrifuges or electromagnetically
or by diffusion. The government program began work on all of
the above to determine which method would work best. Also, in 1940, working at Columbia University,
Fermi and Szilard now began to pursue the chain reaction possibility with uranium and
slow neutrons. They finally selected carbon atoms in the
form of graphite as a moderating material. With government assistance to purchase uranium
and pure graphite, they began to stack graphite blocks with spaces for uranium and make measurements
of the generation of neutrons. In early 1941, they and this work moved to
the University of Chicago. In other government research being carried
out at the University of California at Berkeley, a PhD chemist, Glenn Seaborg, discovered that
when uranium-238 is bombarded by slow neutrons, although it doesn’t fission, it does absorb
slow neutrons and then begins a transformation. It first changes to an unstable isotope of
uranium, and then it quickly transforms itself into a new element, neptunium, which also
has a short life and changes to a new element, plutonium. He then found out that the new plutonium element
was very stable, but under neutron bombardment, it would also fission and release energy and
multiple neutrons, much like the uranium-235 atom. The significant thing about plutonium was
that being a different element than uranium, it could be separated from uranium with a
rather straightforward chemical process. Then the world changes for the United States
with the attack on Pearl Harbor on December 7th, 1941. The pursuit of atomic weapons in the U.S.
goes from laboratory experiments to a military operation. More money is immediately made available to
the labs. In Chicago, this results in the procurement
of tons of graphite and uranium in order to build what Fermi and Szilard call a “pile,”
in order to see if they can achieve the first controlled chain reaction. In the summer of 1942, they begin with bars
of graphite that are four inches by four inches by several feet long, which have holes bored
in them to accept pieces of uranium. They start with small piles to make measurements,
and continued to make larger piles as the materials become available. In the meantime, in the fall of 1942, the
government establishes what became known as the Manhattan Project to centralize all control
over the development of atomic weapons, and appoints newly-promoted General Leslie Groves
as commander. With the discovery of plutonium, there was
now another pressing reason to achieve a controlled chain reaction. In order to produce plutonium in the quantities
needed, a massive source of neutrons would be needed, and it was believed the controlled
chain reaction could be that source. In a squash court under the stadium at the
University of Chicago, Fermi and Szilard begin construction of what they believe will be
a successful demonstration of the world’s first controlled chain reaction. This was a rather massive experiment. The pile eventually reached over 20 feet in
height, was 25 feet wide, and contained 400 tons of graphite and 56 tons of uranium. It also had control and safety rods, which
were wood poles sheathed in cadmium, which absorbs neutrons. It had no shielding and no cooling, as it
was not intended to go beyond a demonstration that a chain reaction could be achieved and
could be controlled. On December 2nd, 1942, they did exactly that,
and the road to Hanford took a giant step. Assuming that the chain reaction experiment
would be successful, three major events were already occurring. The first was a selection by General Groves
of the DuPont Corporation to be the organization that would be responsible for the final design,
construction, and operation of the entire plutonium production portion of the Manhattan
Project. Second, at Chicago, a team of scientists led
by Eugene Wigner was developing the conceptual design for the first full-scale production
reactor. Wigner had a PhD in chemical engineering,
but he was working primarily as a physicist, so he is exceptionally well-suited for this
assignment. They realized that to produce the quantities
of plutonium that would be needed, that the reactor would need to operate at very high
energy levels. This meant they would have to have a very
large cooling source to absorb the vast amounts of heat energy that would be released by the
chain reaction. Their experiments had given them the confidence
that water could be used as a primary coolant, so they needed a production site that had
a very large source of cooling water, in addition to a ready supply of reliable electric energy
nearby to power the giant pumps that they would need. Lastly, they needed a remote site with lots
of open, unpopulated space, since this project would still be an experiment. The third major event was, find a site. General Groves had chosen Lt. Colonel Frank
Mathias for this task, and he and two DuPont engineers began a trip in late December to
look for sites that might fit the criteria that had been established. They looked at sites in California and other
Western states before they flew over the Hanford area on December 22nd, 1942. What they saw was the mighty Columbia River
flowing around several hundred square miles of mostly unpopulated area. They also saw power lines crossing in the
area, coming from newly constructed Grand Coulee Dam upstream and from Bonneville Dam
downstream. This site had it all: an enormous supply of
cold, clean water, a very large source of reliable electric power, and miles of flat,
open area, with very few people who would have to be displaced. They all agreed that this was the place. When they reported their find to General Groves,
he immediately agreed, and Hanford was chosen for the site of plutonium production and the
site for the first production reactor, which came to be named B. That concludes our history lesson of a 45-year
trip from the discovery of the electron in 1897 to the choice of Hanford in 1942. Now we will introduce you to the reactor and
give you a basic idea how it works, how it was built, and introduce you to some of the
models and exhibits you’ll see when you make your visit to B Reactor.
