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Early Nuclear Physics Research
and the
Formation of Crocker Nuclear Laboratory
John Jungerman
Professor Emeritus
With Atomic Energy Commission
(AEC) support, the Department of Physics embarked on the development of
a precision beta ray spectrometer in 1956. Its purpose was to have a high
resolution in order to measure internal conversion electron energies and
from them to investigate nuclear energy levels. A solenoid about ten feet
long and thirty inches in diameter was constructed with correction coils
carefully configured so that the magnetic field over the six-foot helical
electron trajectories would be uniform to one part in ten thousand.
In order to assure uniformity of the field, the solenoid was constructed
of copper ribbon 1-1/4 inches wide and twenty thousandths of an inch thick
wound on edge. A series of some 40 coils each of 120 turns of copper ribbon
and epoxy insulation were fabricated in the Physics Department, which was
then located in a renovated garage, now the annex to the Department of Art.
A commercial firm had failed to produce a satisfactory coil and in the process
had used up our 10% extra length of copper ribbon. Through the skill of
the Physics Department laboratory mechanician, Ralph Rothrock, a precision
jig was constructed and physics faculty and staff successfully wound 50,000
feet of copper ribbon into coils with the requisite mechanical tolerance
and electrical soundness.
The newly-discovered phenomenon of nuclear magnetic resonance was used to
measure the magnetic field and to achieve its uniformity to 0.01% by tailoring
the field with small additional coils. The beta ray spectrometer was an
absolute instrument in that a measurement of the defining slit dimensions
for the conversion electrons and the magnetic field determined the electron
energy. To assure these characteristics, the earth's magnetic field within
the instrument was carefully nullified to less than 1% of its initial value
by means of 6th order correction coils that surrounded the spectrometer.
To increase the utility of the spectrometer we planned to introduce a beam
from a Van de Graaf accelerator at its source point. We would then be able
to precisely measure particle-induced gamma rays via their conversion electrons.
I proposed this idea to Professor Earnest Lawrence seeking his support.
He thought about it for about 10 seconds and then stated, "Yes, a small
cyclotron would be just fine for this purpose." Of course, a cyclotron with
its stray magnetic field was not our first choice for an accelerator, but
I decided that we would somehow shield the spectrometer from the stray field,
and accepted his proposal immediately. Thus the 22-inch cyclotron was born.
Professor Ed McMillan remarked at a later occasion that, "Lawrence thought
you could do anything with a cyclotron."
The 22 inch was designed within the Department of Physics using the then
novel idea of an azimuthal change in the magnetic field giving "sector focusing"
for axial stability of the beam. Neal Peek had a major part in designing
the magnetic field shape, and Bill Knox designed the electrostatic deflector.
We designed the cyclotron to be of variable energy and to produce protons
up to 10 million volts with a similar energy for alpha particles. It began
operating by 1964 and nuclear measurements began using its beams as a prelude
to guiding them to the beta ray spectrometer. Newly-arrived nuclear physicists
Paul Brady and Jim Draper participated in this research. To avoid generating
stray magnetic fields the cyclotron was housed within a steel box with one-inch
thick walls.
Recognizing that the small cyclotron and spectrometer would not be sufficient
for our proposed PhD program, I went to Professor Lawrence again in the
late 1950's to obtain his support for a larger accelerator. As before, he
thought only briefly and then suggested, "Why don't you take the 60 inch?"
This was a world-famous machine which had been used to discover many radionuclides
which are now commonly used such as iodine-131, sodium-24, phosphorus-32
as well as the elements technecium, astatine, neptunium, and plutonium.
It was to be replaced by a modern sector focussing cyclotron, the 88-inch,
which is still operating at Lawrence Berkeley National Laboratory (LBNL).
Naturally, I accepted his offer and we subsequently sought support from
other departments at UCD and generated a proposal for consideration by the
AEC to move the 60 inch to Davis.
Chancellor Emil Mrak and Professor John Jungerman at the beta ray
spectrometer (1961)
The AEC replied upon
review that they would be interested in the proposal provided that we
convert the 60 inch to a modern sector-focussing cyclotron which would
have increased beam intensity and variable energy. By this time (early
1960's) Professor Lawrence had unfortunately passed away. Yet I believe
that his former approval of the transfer to Davis was probably still quite
helpful in our securing support from the AEC. Not only that, but in one
of his last acts as Chancellor of the Berkeley campus before becoming
Chairman of the AEC, Professor Glenn Seaborg authorized the use of a quarter
of a million dollars to move the 60 inch magnet and associated equipment
to Davis. These monies had been earned through charges for use of the
60 inch and were sequestered in a special fund.
Just after the 22-inch began successful nuclear experiments, the AEC program
administrator asked on his yearly visit: "You have a choice. Do you want
to continue running the 22 inch or rather the renovated 60-inch cyclotron"?
This had an easy answer. The 22 inch quickly became surplus to our program
and with it the dream of particle-gamma work with the spectrometer.
Most fortuitously, at this time Bill Knox happened to meet the Dean of
Agriculture of the University of Chile at the annual faculty Steak Bake.
Knox mentioned that we had a surplus cyclotron. Perhaps the physics department
at the University of Chile might be interested? They were. Fortunately
at that time there was a convenio or agreement between the University
of California and the University of Chile financed by the Ford Foundation.
Monies were found for transfer of the 22 inch to Chile. I happened to
be there in 1992 and there was a celebration of 25 years since its first
beam in 1967. The successful transfer of the 22-inch was accomplished
with the aid of personnel from the Department of Physics here. Thus began
a long association and collaboration in nuclear physics between the University
of Chile and UCD.
The 22-inch cyclotron in still running. I remember cringing with some
embarrassment as I watched the Chileans maintaining it with some difficulty
within its one-inch steel encasement.
We began research in how best to modify the 60-inch cyclotron to produce
a modern sector-focussing accelerator. The magnet of the 60 inch was really
72 inches tapered to 60 inches, so we began studies to produce the maximum
energy with a 72 inch magnet. Extensive computer studies of orbit dynamics
were conducted under the direction of Paul Brady. The design gave 100
MeV protons, which was very tempting as there were no sector-focussing
cyclotrons running at that time with this much energy. In a conference
at LBNL with Professor Ed McMillan, Dr. David Judd, chief of the theoretical
division there, and Dr. Elmer Kelly, we were able to convince them of
the soundness of our design in spite of possible non-linearities which
might result because we had used rather extreme values of some of the
magnet parameters. At the conclusion of the meeting McMillan advised:
"You will be remembered not for the extra energy you're trying to get,
but rather for the research that will be done". After considering this
admonishment and the risk of pitfalls with our own design, we decided
to copy a known design of a 76-inch sector-focussing cyclotron then under
construction at Oak Ridge National Laboratory.
The Oak Ridge accelerator has a vertical accelerating region, whereas
the 60-inch magnet was designed for a more conventional horizontal one.
We decided to re-engineer the Oak Ridge design for a horizontal vacuum
tank -- a non-trivial change. We also decided to incorporate an axial
ion source, which had been designed for the new Berkeley 88 inch cyclotron.
This latter source has a more precise location and permits acceleration
of heavy ions or polarized ions much more readily than an ion source that
must extend from the vacuum tank wall. So we bored an eight-inch hole
in the center of the 60-inch magnet to accommodate the axial source and
conducted a series of orbit calculations and magnetic measurements in
the central region. This resulted in a central pole tip shape that gave
the proper axial magnetic focussing at the beginning of a particle's acceleration.
We also added a 2-inch annular steel ring so that the 72-inch magnet became
76 inches in diameter.
Brobeck and Associates helped with the re-engineering, but the Physics
Department staff was responsible for assembling the parts and making it
a functioning accelerator. In a further bureaucratic complexity, we decided
to join with the Naval Research Laboratory in Washington, D.C. in building
their cyclotron. It was also a copy of the ORNL design, but with a new
magnet. The idea was to save money for the U.S. government by building
two cyclotrons together instead of two independently. The collaboration
had its benefits, but there were disadvantages. For example, the Navy
procured the parts, but had no experience with accelerators. The Navy's
submarine service accepted the new dees for our cyclotron. They were
woefully out of tolerance and needed to be extensively modified by the
Physics Department shop.
The cyclotron was completed in 27 months, which was a rather tight schedule.
We produced our first beam just one week before a gala dedication in April,
1966. This was a great relief to all and called for an improptu party
late that evening right in the cyclotron bay. A few months earlier, the
UCD administration decided that the new cyclotron should be a separate
administrative unit to better reflect its utility to the entire campus.
The name Crocker was kept in honor of Regent Crocker and to remind us
of its 60-inch origin at the Crocker Radiation Laboratory on the Berkeley
campus. So Crocker Nuclear Laboratory was created.
The 76-inch cyclotron project was a large one for our small physics department,
but it did firmly establish our research in nuclear physics and greatly
assisted our fledgling Ph.D. program. Neal Peek designed the shielding.
It was arranged so that 30-ton blocks could be lifted off by the overhead
crane to access the accelerator or beam lines. It has served the laboratory
well. Neal was also Assistant Director of CNL for several years. The beam
lines were carefully designed by Jim Draper. They have performed admirably
and have provided the flexibility needed for CNL's diverse research program.
Paul Brady procured the most advanced electronics to support the gathering
and analysis of nuclear data. Bill True headed up the theoretical nuclear
physics group to give us inspiration and guidance.
Chancellor Emil Mrak was a fervent supporter. I remember an occasion in
Berkeley in 1964 when we were about to lose the 2.3 million dollars from
the AEC because the University administration had not yet signed the contract,
which would have expired at the end of the fiscal year -- now a weekend
away. We were near a pay phone. He said: "Jungerman, do you have a dime?"
I guess I did, because he phoned President Wellman and the project was
saved. Mrak provided about a half million dollars of university funds
to put up part of the building to house the cyclotron. When the NSF administrator
came to the campus in response to our proposal, I remember walking over
to the half-completed building with him and the Chancellor. "How about
NSF providing the other half?" he enquired. And they did. It's probably
not done that way any more.
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