- Email: [email protected]
Recent progress in applications of high energy ion beams to nuclear structure and atomic physics
Nuclear Physics A447 (1985) 1570162~ North-Holland, Amsterdam
157c
RECENT PROGRESS IN APPLICATIONS STRUCTURE AND ATOMIC PHYSICS
OF HIGH ENERGY HEAVY ION BEAMS TO NUCLEAR
T.J.M. SYMONS Nuclear Science Division, Lawrence Berkeley California, Berkeley, California 94720*
Laboratory,
University
of
We discuss some recent experiments at the Bevalac which demonstrate the usefulness of relativistic heavy ion beams for study of the nuclear structure of radioactive isotopes.
In the three years that have passed since the first conference series, the study of relativistic
heavy ion collisions
in this
has come of age.
The
most striking manifestation
of this has been the steady stream of new data
obtained
such as the GSI-LBL Plastic Ball, the streamer
using 4n detectors
chambers at Berkeley and Dubna. and the new spectrometer The consequence experimental
DIOGENE at Saclay.
of this effort is that we are at last beginning
to see
results that can be related directly to parameters
equation of state. this conference
These results are discussed
and are summarized
with these developments, of relativistic
of the nuclear
in several contributions
in the talk by H. Stocker.'
another trend can be found.
to
In parallel
This is the application
heavy ion beams to other fields of physics that only a short
time ago would have been unexpected.
In this contribution,
we shall briefly
review the progress that has been made during the last year in the study of nuclear structure relativistic Projectile
and atomic physics using the unique properties
fragmentation
is a process that was studied in some detail in
the first years of Bevalac operation.* relatively
small momentum
separation
of different
consequences.
Firstly,
isotopes by magnetic
on the chemical
isotopes were discovered
produced,
and the ease of
rigidity has two important
isotopes far from stability can be produced with with low energy isotope separators properties
because of the very high detection extended
It was realized early on that the
spread of the fragments
yields that are competitive dependance
of
heavy ion beams.
of the isotope.
efficiency
and without
This comes about
that is possible.
Several new
at the Bevalac3 and these studies have been
using the intense beams that are now available
at GANIL.4
The
*This work was supported in part by the Director, Office of Energy Research, Division of Nuclear Physics of the Office of High Energy and Nuclear Physics of the U.S. Department of Energy under Contract DE-AC03-76SF0009B.
037.5-9474/86/$03.50 OEIsevier Science Publishers B.V. (North-Holland Physics Publishing Division)
T.J.M. Symons /Applications
158~
of high energy heavy ion beams
second important aspect of the fragmentation
process is the copious production
of isotopes that are unstable but not necessarily Because of their small momentum fragments
can be transported
secondary
beams.
spread (Ap/p
at the limits of stability.
1% at 1 GeV/nucleon)
-
through a conventional
these
beam line and used as
Experiments
along these lines have now begun at the Bevalac. In the past year Tanihata and co-workers, 5.6 have carried out a series of
elegant measurements and Li isotopes.
of the reaction cross sections of the particle-stable
In discussing
this experiment,
the final results than on the question
we shall concentrate
of whether these measurements
He
less on
can be
used to extract reliable nuclear structure information. The experiments were 11 using BOO MeV/nucleon B and " Ne beams incident on a Be target
performed
to produce secondary beams which were transported Interaction targets.
cross-sections
Further details of the experimental
references
technique
can be found in
5 and 6.
To relate the measured quantities
to the HISS spectrometer.
were found for each isotope using Be, K and Al
cross-sections
to theoretically
calculable
such as the nuclear radius, the authors developed
procedure.
They first defined an interaction
geometrical
relation dI (p,t) = * [RI (P) + RI
where RI(p) and RI(t) are the interaction and target respectively.
the following
nuclear radius (RI) using the
(t)l
2
(1)
nuclear radii of the projectile
Using this relation, the authors
have deduced RI
for all the particle stable isotopes of He and Li relative to 4He. results are illustrated are clearly visible.
in figure 1.
The
nuclear structure effects 11 For example, the interaction radius of Li is very
much larger than that of 12C .
Significant
It can also be seen that for two nuclei of
the same mass number, the more neutron rich isotope invariably interaction
cross-section.
diffuseness
of the neutron skin as neutrons are added.
has the larger
These effects may be related to the increased
T.J.M. Symons /Applications
-
of high energy heavy ion beams
159c
2.5
E -aa!2.0
1.5 1u
3 A
XBL 856-2809
FIGURE 1 Interaction nuclear radii RT are plotted for all the He and Li isotopes as well as for gE3e and 12C. The dotted lines in the figure indicate an AlI3 dependence on radius. (Taken from reference 6.) When the results of this experiment was expressed compared
suggesting
were first presented,
that it was unclear whether
in a reliable way to a nuclear structure
collaborators
one.
First, they have demonstrated
and target RI values that is assumed
RI value is typically comparison
Tanihata and
that the separability
in equation
well except for the very lightest nuclei such as 4He. Secondly,
RI could in fact be
calculation.
have since gone a long way towards proving that the technique
indeed a powerful projectile
some criticism
1 holds very
The stability
of the
better than 0.1 fm when the target is varied.
they have made a detailed
study of the measured
RI values in
to the rms radii of the stable isotopes 4He, 5Li, 7Li. 'Be
and " C measured
by electron
scattering.
The results are shown in figure 2.
is of
160~
TJM.
Symons /Applications
of high energy heavy ion beams
I
6Li 7Li
1%
gBe
XBL
856-2808
FIGURE 2 The interaction radius, RI, and the rms radius, RF,, (measured bv electron scattering) are plotted for 4He, 6Li 7Li % and 12C. _ Triangles in the figure show the rms radii, RI,, oi Gaussian matter distributions which reproduce the present RT values as discussed in the (Taken from reference 6.) text.
e
The first point to note is that the absolute This is not particularly
not in agreement. disturbing
has now been explained
using a semi-classical this calculation
by the authors
they calculated
Using gaussian wave functions,
optical model.7
What is much more
the nucleon-nucleon
As can be seen. this calculation increases ones confidence
way.
cross-section
parameters
in
and the width parameter to R,,,.
Fixing
at the free nucleon value and adjusting
cross-section.
radius deduced from electron scattering!
nuclear structure.
cross-section
which can be related directly
cross-section
radius to fit the interaction
in a quantitative
the interaction
The only adjustable
are the nucleon-nucleon
of the gaussian distributions
greatly
surprising.
is that the variation with mass number is also quite different.
This difference
figure.
values of RT and RFms are
reproduces
nicely the variation
This is a striking
in the technique
in
result that
as a quantitative
probe of
The next step will be to perform similar calculations
using shell model wavefunctions.
the
they obtain the results in the
T.J.M. Symons /Applications
These pioneering secondary
experiments
are just the beginning
beams and many other possibilities
Minamisono,
These are discussed
Another quite different atomic physics. producing
of nuclei in
opportunities
for secondary
by Kienle in these proceedings.8
application
of relativistic
heavy ion beams is to
High energy heavy ion beams offer the unique possibility
few electron
systems of very high 2 atoms in the laboratory,
example, a beam of "+ U can be prepared Uranium atom in a foil.
However,
needed to do this efficiently. studied the stripping by the Bevalac.'
by stripping the electrons
energies
of
For
from the
in excess of 100 MeV/nucleon
are
As a first step in these studies, Gould et al.
and pick-up of electrons
With this knowledge
shift in He-like Uranium experiment
In particular,
Looking farther into the future, the
project at GSI will provide outstanding
beam studies.
161~
of studies using
are open.
et al. plan to measure ground state magnetic moments
the fp shell using NMR techniques. SIS18/ESR
of high energy heavy ion beams
from high Z atoms accelerated
in hand, a measurement
is now being attempted.
of the Lamb
The first test run for this
has recently taken place and results can be expected within the
next year.
The measurement
will allow high order QED effects to be tested
that are inaccessible
by studies of lighter atoms even
of these measurements
may be very much higher.
these measurements
are without
though the precision
As with the secondary
doubt the beginning
of a new generation
experimental
studies that will be made at our present accelerators 10 those that are just now being constructed.
beams, of
and at
REFERENCES 1) H. Stdcker, this volume. 2) D. E. Greiner et al. Phys. Rev. Lett. 35 (1975) 152. 3) G. D. Westfall
et al. Phys. Rev. Lett. 43 (1979) 1859.
4) M. Langevin et al. Phys. Lett. 1508 (1985) 71. D. Guillemaud-Mueller et al. GANIL Preprint, p.85.08 5) I. Tanihata et al. Phys. Lett. B., in print. I. Tanihata et al., Measurements of Interaction of He Isotopes LBL-18821 (1984). 6) I. Tanihata et al., Measurements of Interaction Radii of Li Isotopes LBL-19904 (1985).
(1985).
Cross Sections and Radii
Cross Sections
and Nuclear
7) P. J. Karol Phys. Rev. Cl1 (1975) 1203. 8) P. Kienle, this volume. 9) H. Gould et al. Phys. Rev. Lett. 52 (1984) 180. 10) H. Gould, New Experiments
on Few-Electron
Very Heavy Atoms LBL-19884
(1985).
157c
RECENT PROGRESS IN APPLICATIONS STRUCTURE AND ATOMIC PHYSICS
OF HIGH ENERGY HEAVY ION BEAMS TO NUCLEAR
T.J.M. SYMONS Nuclear Science Division, Lawrence Berkeley California, Berkeley, California 94720*
Laboratory,
University
of
We discuss some recent experiments at the Bevalac which demonstrate the usefulness of relativistic heavy ion beams for study of the nuclear structure of radioactive isotopes.
In the three years that have passed since the first conference series, the study of relativistic
heavy ion collisions
in this
has come of age.
The
most striking manifestation
of this has been the steady stream of new data
obtained
such as the GSI-LBL Plastic Ball, the streamer
using 4n detectors
chambers at Berkeley and Dubna. and the new spectrometer The consequence experimental
DIOGENE at Saclay.
of this effort is that we are at last beginning
to see
results that can be related directly to parameters
equation of state. this conference
These results are discussed
and are summarized
with these developments, of relativistic
of the nuclear
in several contributions
in the talk by H. Stocker.'
another trend can be found.
to
In parallel
This is the application
heavy ion beams to other fields of physics that only a short
time ago would have been unexpected.
In this contribution,
we shall briefly
review the progress that has been made during the last year in the study of nuclear structure relativistic Projectile
and atomic physics using the unique properties
fragmentation
is a process that was studied in some detail in
the first years of Bevalac operation.* relatively
small momentum
separation
of different
consequences.
Firstly,
isotopes by magnetic
on the chemical
isotopes were discovered
produced,
and the ease of
rigidity has two important
isotopes far from stability can be produced with with low energy isotope separators properties
because of the very high detection extended
It was realized early on that the
spread of the fragments
yields that are competitive dependance
of
heavy ion beams.
of the isotope.
efficiency
and without
This comes about
that is possible.
Several new
at the Bevalac3 and these studies have been
using the intense beams that are now available
at GANIL.4
The
*This work was supported in part by the Director, Office of Energy Research, Division of Nuclear Physics of the Office of High Energy and Nuclear Physics of the U.S. Department of Energy under Contract DE-AC03-76SF0009B.
037.5-9474/86/$03.50 OEIsevier Science Publishers B.V. (North-Holland Physics Publishing Division)
T.J.M. Symons /Applications
158~
of high energy heavy ion beams
second important aspect of the fragmentation
process is the copious production
of isotopes that are unstable but not necessarily Because of their small momentum fragments
can be transported
secondary
beams.
spread (Ap/p
at the limits of stability.
1% at 1 GeV/nucleon)
-
through a conventional
these
beam line and used as
Experiments
along these lines have now begun at the Bevalac. In the past year Tanihata and co-workers, 5.6 have carried out a series of
elegant measurements and Li isotopes.
of the reaction cross sections of the particle-stable
In discussing
this experiment,
the final results than on the question
we shall concentrate
of whether these measurements
He
less on
can be
used to extract reliable nuclear structure information. The experiments were 11 using BOO MeV/nucleon B and " Ne beams incident on a Be target
performed
to produce secondary beams which were transported Interaction targets.
cross-sections
Further details of the experimental
references
technique
can be found in
5 and 6.
To relate the measured quantities
to the HISS spectrometer.
were found for each isotope using Be, K and Al
cross-sections
to theoretically
calculable
such as the nuclear radius, the authors developed
procedure.
They first defined an interaction
geometrical
relation dI (p,t) = * [RI (P) + RI
where RI(p) and RI(t) are the interaction and target respectively.
the following
nuclear radius (RI) using the
(t)l
2
(1)
nuclear radii of the projectile
Using this relation, the authors
have deduced RI
for all the particle stable isotopes of He and Li relative to 4He. results are illustrated are clearly visible.
in figure 1.
The
nuclear structure effects 11 For example, the interaction radius of Li is very
much larger than that of 12C .
Significant
It can also be seen that for two nuclei of
the same mass number, the more neutron rich isotope invariably interaction
cross-section.
diffuseness
of the neutron skin as neutrons are added.
has the larger
These effects may be related to the increased
T.J.M. Symons /Applications
-
of high energy heavy ion beams
159c
2.5
E -aa!2.0
1.5 1u
3 A
XBL 856-2809
FIGURE 1 Interaction nuclear radii RT are plotted for all the He and Li isotopes as well as for gE3e and 12C. The dotted lines in the figure indicate an AlI3 dependence on radius. (Taken from reference 6.) When the results of this experiment was expressed compared
suggesting
were first presented,
that it was unclear whether
in a reliable way to a nuclear structure
collaborators
one.
First, they have demonstrated
and target RI values that is assumed
RI value is typically comparison
Tanihata and
that the separability
in equation
well except for the very lightest nuclei such as 4He. Secondly,
RI could in fact be
calculation.
have since gone a long way towards proving that the technique
indeed a powerful projectile
some criticism
1 holds very
The stability
of the
better than 0.1 fm when the target is varied.
they have made a detailed
study of the measured
RI values in
to the rms radii of the stable isotopes 4He, 5Li, 7Li. 'Be
and " C measured
by electron
scattering.
The results are shown in figure 2.
is of
160~
TJM.
Symons /Applications
of high energy heavy ion beams
I
6Li 7Li
1%
gBe
XBL
856-2808
FIGURE 2 The interaction radius, RI, and the rms radius, RF,, (measured bv electron scattering) are plotted for 4He, 6Li 7Li % and 12C. _ Triangles in the figure show the rms radii, RI,, oi Gaussian matter distributions which reproduce the present RT values as discussed in the (Taken from reference 6.) text.
e
The first point to note is that the absolute This is not particularly
not in agreement. disturbing
has now been explained
using a semi-classical this calculation
by the authors
they calculated
Using gaussian wave functions,
optical model.7
What is much more
the nucleon-nucleon
As can be seen. this calculation increases ones confidence
way.
cross-section
parameters
in
and the width parameter to R,,,.
Fixing
at the free nucleon value and adjusting
cross-section.
radius deduced from electron scattering!
nuclear structure.
cross-section
which can be related directly
cross-section
radius to fit the interaction
in a quantitative
the interaction
The only adjustable
are the nucleon-nucleon
of the gaussian distributions
greatly
surprising.
is that the variation with mass number is also quite different.
This difference
figure.
values of RT and RFms are
reproduces
nicely the variation
This is a striking
in the technique
in
result that
as a quantitative
probe of
The next step will be to perform similar calculations
using shell model wavefunctions.
the
they obtain the results in the
T.J.M. Symons /Applications
These pioneering secondary
experiments
are just the beginning
beams and many other possibilities
Minamisono,
These are discussed
Another quite different atomic physics. producing
of nuclei in
opportunities
for secondary
by Kienle in these proceedings.8
application
of relativistic
heavy ion beams is to
High energy heavy ion beams offer the unique possibility
few electron
systems of very high 2 atoms in the laboratory,
example, a beam of "+ U can be prepared Uranium atom in a foil.
However,
needed to do this efficiently. studied the stripping by the Bevalac.'
by stripping the electrons
energies
of
For
from the
in excess of 100 MeV/nucleon
are
As a first step in these studies, Gould et al.
and pick-up of electrons
With this knowledge
shift in He-like Uranium experiment
In particular,
Looking farther into the future, the
project at GSI will provide outstanding
beam studies.
161~
of studies using
are open.
et al. plan to measure ground state magnetic moments
the fp shell using NMR techniques. SIS18/ESR
of high energy heavy ion beams
from high Z atoms accelerated
in hand, a measurement
is now being attempted.
of the Lamb
The first test run for this
has recently taken place and results can be expected within the
next year.
The measurement
will allow high order QED effects to be tested
that are inaccessible
by studies of lighter atoms even
of these measurements
may be very much higher.
these measurements
are without
though the precision
As with the secondary
doubt the beginning
of a new generation
experimental
studies that will be made at our present accelerators 10 those that are just now being constructed.
beams, of
and at
REFERENCES 1) H. Stdcker, this volume. 2) D. E. Greiner et al. Phys. Rev. Lett. 35 (1975) 152. 3) G. D. Westfall
et al. Phys. Rev. Lett. 43 (1979) 1859.
4) M. Langevin et al. Phys. Lett. 1508 (1985) 71. D. Guillemaud-Mueller et al. GANIL Preprint, p.85.08 5) I. Tanihata et al. Phys. Lett. B., in print. I. Tanihata et al., Measurements of Interaction of He Isotopes LBL-18821 (1984). 6) I. Tanihata et al., Measurements of Interaction Radii of Li Isotopes LBL-19904 (1985).
(1985).
Cross Sections and Radii
Cross Sections
and Nuclear
7) P. J. Karol Phys. Rev. Cl1 (1975) 1203. 8) P. Kienle, this volume. 9) H. Gould et al. Phys. Rev. Lett. 52 (1984) 180. 10) H. Gould, New Experiments
on Few-Electron
Very Heavy Atoms LBL-19884
(1985).