63 Recent Developments at T R I S T A N Nuclear Structure Studies of Neutron-Rich Nuclei R. L. Gill Brookhaven National Laboratory, Upton, NY 11973
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The nuclear physics program at the fission product mass separator, TRISTAN, has greatly expanded, both in the types of experiments possible and in the range of nuclei available. Surface ionization, FEBIAD, high-temperature thermal, high-temperature plasma, and negative surface ionization ion sources are routinely available. Experi mental facilities developed to further expand the capa bilities of TRISTAN include a superconducting magnet for g-factor and Q measurements, a windowless Si(Li) detector for conversion electron measurements, and a colinear fast-beam dye laser system for hyperfine inter action studies. This combination of ion sources, experimental apparatus, and the long running time avail able at a reactor makes TRISTAN a powerful tool for nuclear structure studies of neutron-rich nuclei. The effect of these developments on the nuclear physics program at TRISTAN will be discussed and recent results from some of these facilities will be presented. β
The TRISTAN F a c i l i t y A schematic layout of the TRISTAN ISOL f a c i l i t y 1. High
A neutron
beam of about
Flux Beam Reactor
3xl0
1 0
2
n /cm /sec tn
i s shown i n F i g .
i s provided by the 60 MW
at Brookhaven N a t i o n a l Laboratory.
Targets which
235
t y p i c a l l y contain 5g
U i n s i d e an i o n source are positioned i n the neutron
beam to provide intense beams of s h o r t - l i v e d n e u t r o n - r i c h n u c l e i produced by fission. used,
To provide f o r maximum v e r s a t i l i t y ,
each
of which i s best
suited
a v a r i e t y of i o n sources are
to producing c e r t a i n
elements
GIL85, PI084]. 0097-6156/ 86/ 0324-0420$06.00/ 0 © 1986 American Chemical Society
Meyer and Brenner; Nuclei Off the Line of Stability ACS Symposium Series; American Chemical Society: Washington, DC, 1986.
[SHM83,
Nuclear Structure Studies of Neutron-Rich Nuclei
GILL
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63.
421
Fig.
2.
Schematic diagram of the high temperature plasma i o n source.
High Temperature Plasma Ion Source The
most
plasma i o n source.
recently
developed
i o n source
The source i s shown i n F i g . 2.
i s the high
temperature
I t i s constructed i n a
fashion s i m i l a r to the thermal and negative i o n sources i n that these three sources
share
shields. fied
a
common
design
f o r the
t a r g e t , heating
owing to s t a n d a r d i z a t i o n of the designs.
that t h i s
filamental
heat
Thus, mass production and assembly of the sources has been s i m p l i Off-line
i o n source e x h i b i t s i o n i z a t i o n e f f i c i e n c i e s
studies have shown
of up to 60% f o r Kr
Meyer and Brenner; Nuclei Off the Line of Stability ACS Symposium Series; American Chemical Society: Washington, DC, 1986.
422
NUCLEI OFF THE LINE OF STABILITY
and Xe i n the low pressure l i m i t . elements ture
This source produces
the same v a r i e t y of
as the FEBIAD source, but due to the l a r g e r target, higher tempera
and
high
ionization
efficiency,
the
intensities
of
the
radioactive
beams are s i g n i f i c a n t l y higher than with the FEBIAD source. Experimental F a c i l i t i e s In F i g . 1, the f a c i l i t i e s a v a i l a b l e at each of the f i v e beam ports at TRISTAN are l a b e l e d . ences t h e r e i n . become
fully
The
Si(Li)
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facilities
o p e r a t i o n a l and
f a c i l i t i e s w i l l now
electron
The
widely
used
in
the
past
year.
Detector.
A
windowless
Si(Li)
i n a cryostat
detector
These
two
be moved to w i t h i n 5 mm
f o r conversion
with a compressable
to a vacuum chamber and moving tape c o l l e c t o r .
radioactive
refer
be described i n some d e t a i l .
spectroscopy i s housed
connected
are described i n [GIL85] and
S i ( L i ) detector and superconducting magnet systems have
of the surface of an aluminized mylar
ion beams are implanted.
The
tape system
that the ion beam d e p o s i t i o n point i s d i r e c t l y viewed located i n an area shielded from the d e t e c t o r .
bellows
The detector can tape on which
can be configured so by the detector or i s
In the l a t t e r
configuration,
the tape must be moved before the S i ( L i ) detector can view the source. problem
encountered
neutron-rich desired gating
nuclei
peaks.
i s used
doing
i s the
This
techniques.
response)
when
conversion
tendency
interference A
thin
of
can
plastic
to suppress
the
be
3
suppressed
by
to
very
Si ( L i )
with
obscure
employing
(with
i n the
One
spectroscopy
continuum
scintillator
3 signal
the
electron
the
various
low
γ-ray
detector.
The
system i s designed such that a standard Ge detector cryostat also views the same source as the S i ( L i ) d e t e c t o r .
Thus, γ-ray e l e c t r o n and x-ray e l e c t r o n
coincidences can also be employed to enhance the e l e c t r o n s i g n a l , as w e l l as provide f o r element i d e n t i f i c a t i o n . bilities, it
In a d d i t i o n to these coincidence capa
e l e c t r o n and γ-ray s i n g l e s can be simultaneously acquired, making
possible
to measure
internal
conversion c o e f f i c i e n t s .
been used to i d e n t i f y weakly populated 0 Superconducting magnet system,
Magnet.
manufactured
f o r g-f a c t o r and
A
by Oxford
Q3 measurements.
s e c t i o n room temperature for
the
tape
from
states i n
96
split-pole, Instruments,
The
Τ at 108 A at 4°K with inhomogeneity
,
+
>
magnet has a f i e l d 2
tape
collector.
The
has
superconducting
i s available
of +
nucleus
where
N
-
Ν /Ν ,
a
observed
straight only
± 0.05)
can be described
t
f o r isotopes
ν
g(2+!) » (0.24
for
ltf6
Ν
of
line
f o r those
π
+
N .
If
v
Ba-Dy
by
are used
i s obtained
with
isotopes expected
the
deviations
are i n a d i r e c t i o n
I f only those
± 0.04 and g of g
nuclei
i n this
used
v
*
+
g(2 i)
significant to e x h i b i t
a
shell
state i n N
gπNπ/ t values
t
are accepted
as being
+
of
versus
v
deviations a truncated
being proton
A d d i t i o n a l l y , a l l of the smaller
proton
valence
isotopes with N>90 are included i n the f i t g I f these e m p i r i c a l l y constant
over
region, then the experimentally determined
ir
- 0.63
determined
a wide range of g - f a c t o r s can be (Ν
π
i n IBA-2
The r e s u l t s of t h i s a n a l y s i s are shown i n F i g . 3 f o r Ba, Ce,
and Sm i s o t o p e s .
major
+
N /N
as a measure of the e f f e c t i v e number of valence protons
formalism). Nd,
and g
ir
+
g(2 i)
experimental
to p l o t
indicates
- 0.05 ± 0.05 i s obtained.
v
values
that
The
C e and g ( 2 x ) - (0.37 ±
[SAM84]
valence space due to the s u b s h e l l c l o s u r e at Z=64.
space.
technique
+
In IBA-2 formalism, the g - f a c t o r of the f i r s t 2
g(2 i) π
cascade) are measured at an a p p r o p r i
down.
[W0L83] since t h i s technique e l i m i n a t e s most systematic e r r o r s .
r e s u l t s obtained are: 0.06)
+
The dashed
closures from
line
shows the value of Ν
Z-50-82 (Z-82) and from
π
expected f o r
Z-50-64 (Z-64) and the
s o l i d l i n e i n d i c a t e s the region of t r a n s i t i o n between s h e l l s
[GIL82],
figure
a tendency of
the
Ν
shows not only π
change
the d i s t i n c t
to s h i f t
to lower
change neutron
i n Ν , but also π
number
as Ζ i n c r e a s e s .
Meyer and Brenner; Nuclei Off the Line of Stability ACS Symposium Series; American Chemical Society: Washington, DC, 1986.
The
This
63.
Nuclear Structure Studies of Neutron-Rich Nuclei
GILL
425
T
Ba
6
Ce Z = 82
4
Ζ =82 Ζ = 64
2
Z = 64
Nd
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6
Ζ =82
4 Z = 64
2
-È
L
84
86
_l_
88
_L
90
92
84
86
88
90
92
Ν Fig. and
3.
Ν
β ί π
*
deduced
f o r isotones of Ba, Ce, Nd, and Sm.
Sm data are from [WOL83] and references t h e r e i n .
The Ba,
Nd,
The Ce data i s from
t h i s work.
effect
i s primarily
becoming
possible
neutron-proton are occupying
due to e a r l i e r
as higher
orbitals
occupation are f i l l e d
of the with
hn/2
increasing
i n t e r a c t i o n can then operate to the f u l l e s t the ho/2 o r b i t a l ) r e s u l t i n g
ïï
extent
orbital Z.
i n a deformed nucleus having the
lowest energy. Acknowledgment Research supported under contract DE-AC02-76CH00016 with the U.S. DOE.
References [SHM83] M. Shmid et al., NIM 211 287 (1983). [GIL85] R. L. Gill and A. Piotrowski, NIM 234 213 (1985). [PIO84] A. Piotrowski et al., NIM 224 1 (1984). [WOL83] A. Wolf et al., Phys. Lett. 123B 165 (1983). [SAM84] M. Sambataro et al., Nucl. Phys. A423 333 (1984). [GIL82] R. L. Gill et al., Phys. Lett. 118B 251 (1982). RECEIVED
The
(neutrons
July 14, 1986
Meyer and Brenner; Nuclei Off the Line of Stability ACS Symposium Series; American Chemical Society: Washington, DC, 1986.
