sonja orrigo
DESCRIPTION
Sonja Orrigo. Correlation effects and continuum spectroscopy in light exotic nuclei. Unbound Nuclei Workshop, Pisa, Italy, November 3-5, 2008. Contents. Physical scenario: light exotic nuclei Correlations effects and continuum spectroscopy DCP correlations: Fano resonances - PowerPoint PPT PresentationTRANSCRIPT
Sonja Orrigo
Correlation effects and continuum spectroscopy in light exotic nuclei
Unbound Nuclei Workshop, Pisa, Italy, November 3-5, 2008
ContentsContents
Physical scenario: light exotic nuclei
Correlations effects and continuum spectroscopy
DCP correlations: Fano resonances Experimental results on 11Be and 15C via CEX
reactions
Pairing correlations in the continuum Transfer reactions to unbound states: 9Li(d,p)10Li
Summary and conclusions
Why correlation effects in light exotic nuclei?Why correlation effects in light exotic nuclei?
light
n-r
ich
nucl
ei
D
isso
lutio
n of
she
ll st
ruct
ures
In
fluen
ce o
f cor
rela
tion
dyna
mic
s
Peculiar conditions:Large charge asymmetry
Weak binding of valence n
Proximity of s.p. continuumlow density (halos)
isovector interaction
open quantum systems
Continuum spectroscopy of light exotic nucleiContinuum spectroscopy of light exotic nuclei
Two topics:
• 15C: weakly-bound Sn = 1218 keV
effects due to the DCP correlation dynamics Fano Resonances
• 10Li: n-unbound by 25 keV
effects due to pairing correlations
continuum spectroscopy by one-neutron transfer s.p. excitations
• Dynamical Core Polarization (DCP) correlations• Pairing correlations
Im
porta
nt to
inve
stig
ate
thei
r ef
fect
s in
the
low
-ene
rgy
cont
inuu
m
ContentsContents
Physical scenario: light exotic nuclei
Correlations effects and continuum spectroscopy
DCP correlations: Fano resonances Experimental results on 11Be and 15C via CEX
reactions
Pairing correlations in the continuum Transfer reactions to unbound states: 9Li(d,p)10Li
Summary and conclusions
Fano ResonancesFano Resonances
Fano ResonancesFano Resonances are investigated as a new a new
continuum excitation modecontinuum excitation mode in exotic nuclei
Atomic physics• H.Feshbach, Ann. of Phys. 5 p. 357 (1958), Ann. of Phys. 19 p. 287 (1962), Ann.
of Phys. 43 p. 410 (1967) • F.H.Mies, Phys. Rev. 175 p. 164 (1968)• A.F.Starace, Phys. Rev. B 5 p. 1773 (1972)• A.K.Bhatia and A.Temkin, Phys. Rev. A 29 p. 1895 (1984)• J.P.Connerade and A.M.Lane, Rep. on Progr. in Phys. 51 p. 1439 (1988)
Hadron physicsN.E.Ligterink, PiN Newslett. 16 p. 400nucl-th/0203054 (2002)
Solid-state physics• S.Glutsch, Phys. Rev. B 66 p. 075310 (2002)
Nuclear physicsG.Baur and H.Lenske, Nucl. Phys. A 282p. 201 (1977)
General phenomenon observed in many different areas of physics
Fano interferenceFano interference
Originally detected in atomic spectra
1960’s, Fano: first model for atomic states excited in the inelastic scattering e--atoms
Typical for interacting many-body
systems at all scales !
Fano interferencequantum-mechanical interaction betweendiscrete and continuous configurations asymmetric line shape
Fano Resonances in nuclear physicsFano Resonances in nuclear physics
BSEC: narrow resonances in the continuum (Ex > Sn)
DCP model: BSEC as quasi-bound core-excited configurationsExperimental signature of the DCP correlations
G.Baur and H.Lenske, Nucl. Phys. A 282(1977)201; H.Lenske et al., Jour. Progr. Part. Nucl. Phys. 46(2001)187
Predicted theoretically by Mahaux and Weidenmüller (1969)C.Mahaux and H.A.Weidenmüller, Shell Model Approach to Nuclear Reactions, North-Holland, Amsterdam (1969)
1st observed BSEC (1980): 13C (stable), Ex = 7.677 MeV (J = 3/2+)H.Fuchs et al., Nucl. Phys. A 343(1980)133
Bound States Embedded in the Continuum (BSEC)
And in exotic nuclei?
In exotic nucleiIn exotic nuclei
n-dripline nuclei:easily polarizable core
BSEC at low-energy
C-isotopes: presence of
low-energy 2+ core states
good candidates
Importance of a
systematic study
H. Lenske, from HFB & QRPA calculations
Fano Resonances in exotic nucleiFano Resonances in exotic nuclei
F.Cappuzzello, S.E.A. Orrigo et al., EuroPhys. Lett. 65 p. 766 (2004)
S.E.A. Orrigo et al., Proceedings Varenna 122 p. 147 (2003)
35
30
25
20
15
10
5
0
8.50*
8.507.30
7.30*
6.77] 6.4
g.s.
g.s.*
0.77
lab = 14°, 55 keV/ch
0 2 4 6 8 10 12
15C Excitation energy [MeV]Counts
DCP regime
Single particle regime
S n
0.77*
Fano interference:BSEC – s.p. continuum
8.50*L=8°109 keV/ch
15C Excitation energy [MeV]
Cou
nts
7.30
8.50
1515N(N(77Li,Li,77Be)Be)1515C @ 55 MeVC @ 55 MeV
1515N(N(77Li,Li,77Be)Be)1515C @ 55 MeVC @ 55 MeV
F.Cappuzzello, S.E.A. Orrigo et al., EuroPhys. Lett. 65 p. 766 (2004)S.E.A. Orrigo et al., Proceedings Varenna 122 p. 147 (2003);
a) level densitynatural parity transitions
0 2 4 6 8 10 12 1415C Excitation energy [MeV]
10 2
10
1
10 2
10 1
dQ
RPA
()
[MeV
1]
b) level densityunnatural parity transitions
0 2 4 6 8 10 12 1415C Excitation energy [MeV]
dQ
RPA
()
[MeV
1]
s. p.
s. p.
Sn
Sn
Results of microscopic QRPA calculations
Ex [MeV] [keV]0.00 0.030.77 0.036.77 0.06 < 1607.30 0.06 < 708.50 0.06 < 140
8.50*
8.50
7.307.30*6.77] 6.4
g.s.
g.s.*
0.77
DCP regime
Single particle regime
S n
0.77*
0 2 4 6 8 10 12 15C Excitation energy [MeV]
35
30
25 20
15
10
5
0
Counts
lab = 14°55 keV/ch
Strength well reproduced for single particle transitions
(1/2+ g.s., 5/2+ state at 0.77 MeV)
Observed fragmentation for Ex > 2 MeV not reproduced
15C: Fano Resonances• Strong competition of mean-field and correlation dynamics
mean-field approaches are no longer appropriate• Enhanced correlation effects (Dynamical Core Polarization DCP)
new excitation modes involving core-excited configurations (BSEC)
1111B(B(77Li,Li,77Be)Be)1111Be @ 57 MeVBe @ 57 MeV
a) level densitynatural parity transitions
0 2 4 6 8 10 12 1411Be Excitation energy [MeV]
dQ
RPA
()
[MeV
1]
b) level densityunnatural parity transitions
0 2 4 6 8 10 12 1411Be Excitation energy [MeV]
dQ
RPA
()
[MeV
1]
s. p.
s. p.
QRPA calculations
F.C
appu
zzel
lo, H
.Len
ske
et a
l.,
Phy
s. L
ett B
516
(200
1)21
7Be detected with the IPN-Orsay Split-Pole magnetic spectrometer
DCP regimeSingleparticle
0 1 2 3 4 5 6 7 811Be Excitation energy [MeV]S n
Counts
Strength well reproduced for single particle transitions
(1/2+ g.s., 1/2- state at 0.32 MeV and 5/2+ state at 1.77 MeV)
Observed fragmentation for Ex > 2 MeV not reproduced
The QPC modelThe QPC model
H.L
ensk
e, J
. Phy
s. G
: Nuc
l. P
art.
Phy
s. 2
4 (1
998)
142
9H
.Len
ske,
C.M
.Kei
l, N
.Tso
neva
, Pro
gr. i
n P
art.
and
Nuc
l. P
hys.
53
(200
4)
153
Q
uasi
part
icle
-cor
e co
uplin
g (Q
PC) m
odel
(B
ohr &
Mot
tels
on)
DC
P c
orre
latio
ns d
escr
ibed
by
coup
ling
1QP
to th
e co
re-e
xcite
d co
nfig
urat
ions
1QP
3Q
P
Cor
e ex
cita
tions
: 2Q
P e
xc. g
iven
by
QR
PA
Strength fragmentation not reproduced by QRPA DCP effects
3331
1311
HVVH
H
QP
C H
amilt
onia
n of
the
odd-
mas
s sy
stem
:
Jn11H
JC )J (j'33H
3Q
P s
tate
s
1QP
sta
tes
coupled by V13
To study resonances in the low-energy continuum and their line shapes
Theoretical modelTheoretical model
3331
1311
HVVH
H
QP
C e
igen
stat
es:
0φ E)(H J
S.E
.A.O
rrig
o, H
.Len
ske
et a
l., P
hys.
Let
t. B
633
(200
6) 4
69
CJj'JC πππ ;J 'jJ
C
CJ j'
JCJ j'Jεn
JnJ )J (j')E(zε)E(z dεn)E(z φ
s.p. mixing
1QP
3Q
P
E < 0bound states
E> 0continuum
BS
EC
(EC)
Bou
nd c
ore-
exci
ted
stat
es (E
– E
C <
0)
Theoretical modelTheoretical model
Coupling of a single particle elastic channel to closed core-excited channels
By projecting the Schrödinger equation onto the 1-QP and 3-QP components N coupled equations
1QP Channel 1
3QP Channels i = 2, …,
N
0 J V0 εh 'J j'
C131)1(
jC
cJjj
0 0VJ εhn
13C'i(i)
J j' C jJj c
Ch. 1 1QP
continuum
Ch. i = 2, …, N 3QP states
0ε , ,h 1)1(
j j
0Eεε , ,h (i)C1i'
(i)J j' C
cJj
S.E
.A.O
rrig
o, H
.Len
ske
et a
l., P
hys.
Let
t. B
633
(200
6) 4
69
Numerical methodsNumerical methodsThe coupled channels problem is solved in coordinate space
N coupled equations for the radial wave functions
0 (r)u W(r)u N
2 i i,i 1,
212
112
2
i1K
r1)(
drd
0 (r)u W(r)u Kr
1)(drd
1i 1,i i,2i2
ii2
2
1QP Channel 1 (open)
3QP Channels i = 2, …,
N(closed) 2
ii2i Uε 2mK
2i
2i ε 2mk
r < RA
r >> RA
Pot
entia
ls U
i fro
m H
FB c
alcu
latio
ns
2(i)Ji C
F 2mW 0(i)JC13
(i)J F βJV0F
CC
Tra
nsiti
on fo
rm fa
ctor
s fro
m
QR
PA
cal
cula
tions
& d
ata
S.E
.A.O
rrig
o, H
.Len
ske
et a
l., P
hys.
Let
t. B
633
(200
6) 4
69
Numerical methodsNumerical methods
r)(Q (r) b (r) b (r)u N
1 mmm im
N
1 mm im i, ii
a
jχr < RA
i = 1, …, N
1) Internal w.f. by solving the NxN eigenvalue problem
r)(k C r)(k(r)u i)(
i11i1 i, i1i
hj r >> RA
2) Asymptotic w.f.
i = 1, …, N
0
0'0
0
C
CCb
bb
1
1
1N
12
11
N
2
1
''
j
j
h
h
χ
χ)(Ru)(Ru M
)2( i,M
)1( i,
Matching 2N equations with complex coefficients
drd
drd )(Ru)(Ru M
)2( i,M
)1( i,
AM RR
bm, C1i
2ii2
iii (k)C
121j2
kπ4 )k(σ
s i = 1, …, N
S.E
.A.O
rrig
o, H
.Len
ske
et a
l., P
hys.
Let
t. B
633
(200
6) 4
69
Results for Results for 1515CC
Elastic scattering cross section
2112
111 (k)C
121j2
kπ4 )k(σ
s
Analytic calculation for 2 ch.
A single excited state of the
14C core: EC = 8.317 MeV
Ui from HFB
V13 is the only free parameter
0
2
4
6
8
10
12
0 5 10 15 20 25 30
s-wave p-wave d-wave
15C excitation energy [MeV]
11
[mb]
V13 = 0
S.E
.A.O
rrig
o, H
.Len
ske
et a
l., P
hys.
Let
t. B
633
(200
6) 4
69
0
2
4
6
8
10
12
0 5 10 15 20 25 30
s-wave p-wave d-wave
V13 0 11
[mb]
15C excitation energy [MeV]
Fano interference
s-, p-, d-waves
Results for Results for 1515CC
15C theo. (11 d-wave)
V13 is the only free parameter15C exp. from (7Li,7Be)
Full 5-channels calculation
4 14C states: EC(J) = 6.094(1–),6.728(3–), 7.012(2+), 8.317(2+) MeV
Ui from HFB
V13 weighted by (i) of 14C(,’)JC
Q
ualit
ativ
e co
mpa
rison
:E
th. =
6.6
7, 7
.36,
7.7
0, 8
.92
MeV
th
. = 6
6, 8
0, 1
41, 8
5 ke
V
Eex
p. =
(6.7
7, 7
.30,
8.5
0)
0.0
6 M
eV
exp. ≤
160
, 70,
140
keV
V13 affects of the resonances
(here V13 = 5 MeV)
S.E
.A.O
rrig
o, H
.Len
ske
et a
l., P
hys.
Let
t. B
633
(200
6) 4
69
Results Results for for 1717C and C and 1919CC
Sta
te p
aram
eter
s by
QR
PA
V13 is the only free parameter (here 5 MeV)
18 C
sta
tes:
EC(J
) =
1.6
20(2
+ ),
2.96
7(4+ )
, 3.3
13(2
+ ), 5
.502
(1– )
MeV
16 C
sta
tes:
EC(J
) =
1.7
66(2
+ ),
3.98
6(2+ )
, 4.1
42(4
+ ) M
eV
0
10
20
30
40
50
60
70
0 2 4 6 8 10 12
d-wave
11 [m
b]
17C excitation energy [MeV]
1717CCSSnn = 0.73 MeV = 0.73 MeV
0102030405060708090
100
0 2 4 6 8 10 12
d-wave
11
[mb]
19C excitation energy [MeV]
1919CCSSnn = 0.16 MeV = 0.16 MeV
BS
EC
stru
ctur
es m
ove
tow
ards
low
er e
nerg
ies
with
incr
easi
ng th
e ne
utro
n ex
cess
Incr
ease
d ef
fect
of t
he c
orre
latio
ns
Systematic study of the evolution of the phenomenon when going towards more n-rich nuclei
S.E.A. Orrigo, H.Lenske et al., Proceedings INPC07, Tokyo
The (The (77Li,Li,77Be) CEX reactionBe) CEX reactionStructural properties:
• Single particle isovector excitations
• BSEC and Fano resonancesin the continuum
Reaction dynamics:• One-step / two-step contributions
• Spin transfer probabilities
N = 1 7He N = 2 11Be N = 3 15C N = 4 19O N = 5 23Ne N = 6 27Mg …
N + 3 n
MA
GN
EX I
PN-O
rsay
References:
S.E.A. Orrigo et al., Core excited Fano-resonances in exotic nuclei, Phis.Lett. B 633(2006)469
F.Cappuzzello, S.E.A. Orrigo et al., Excited states of 15C, EuroPhys.Lett. 65(2004)766
F.Cappuzzello et al., Analysis of the 11B(7Li,7Be)11Be reaction at 57 MeV in a Microscopic Approach, Nucl.Phys. A 739(2004)30
S.E.A. Orrigo et al., Spectroscopy of 15C by (7Li,7Be) Charge Exchange Reaction, Proc. “10th Int. Conf. on Nuclear Reaction Mechanisms” , Varenna, Italy, 122(2003)147
C.Nociforo et al., Investigation of light neutron-rich nuclei via the (7Li,7Be) reaction, Acta Physica Polonica, B 34(2003)2387
F.Cappuzzello et al., Excited states of 11Be, Phys.Lett B 516(2001)21
Maximum magnetic rigidity 1.8 T• m
Solid angle 51 msr
E max /E min 1.7Total energy resolution(target 1 mm2, 90% of full acceptance) 1000
Mass resolution 250
A.Cunsolo et al., NIMA 481 (2002) 48
A.Cunsolo et al., NIMA 484 (2002) 56
E < 30 AMeV
2 < A < 40
E < 25 AMeV
40 < A < 93
Upper bent limits
1919F(F(77Li,Li,77Be)Be)1919O @ 52.4 MeVO @ 52.4 MeV
Xfoc [m]
Counts
= 50 msrEnergy byte = ± 27%
PRELIMINARY
g.s.
96 keV19O
E/E ~ 1000
lab = 7° - 19.5°
19.8 keV/ch
Sn = 3.9 MeV
ContentsContents
Physical scenario: light exotic nuclei
Correlations effects and continuum spectroscopy
DCP correlations: Fano resonances Experimental results on 11Be and 15C via CEX
reactions
Pairing correlations in the continuum Transfer reactions to unbound states: 9Li(d,p)10Li
Summary and conclusions
Single particle dynamics: the relevant energy scale is Sn
• Stable nuclei: Sn~10MeV
→ static MF in the p-h channel + paring for the p-p correlations
• Weakly-bound n-rich nuclei: Sn~few keV-MeV→ pairing correlations in the p-h channel are also important
Theory of Pairing in the ContinuumTheory of Pairing in the Continuum Extended MF approach for pairing in weakly-bound or unbound nuclei
• 2x2 coupled channel problem described by the Gorkov equationsH.Lenske, F.Hofmann, C.M.Keil, J. Progr. Part. Nucl. Phys. 46(2001)187
Particle channel (open)
Hole channel (closed)
mjn Ee field Pairingr MFrU
qqqq αα
energy) (QP 02
eeE n)p,(q potential chemical
αααq
0rvru
erUTrΔ
rΔerUT
α
α
αqq†q
qαqq
Similarity between the Pairing and DCP approaches
Particle-stable system: q<0
• e <0 , hole w.f. v decaying exponentially for r»RA
• In the continuum e+>0, particle w.f. u like a scattering wave: 1u (r) cos F (r) sin G (r)
k r
Theory of Pairing in the ContinuumTheory of Pairing in the Continuum
The same type of effects is produced by any types of correlations (e.g., DCP → Fano)
2j j2
2j 1 4(E) sin (E)2s 1 k
Partial wave elastic scattering cross section:
Resonances in resonances in ℓjCorr
Observables involving the states u will show a characteristic energy dependence
(e.g., transfer cross sections through S(E))
CorrMF (c) (c)u (r) cos f (r) sin g (r) αα
†α2
α(c)α ugf
4πmkδtan
Relationship scattering observables – pairing strength
Continuum level density: spectral distribution of particle strength per energy E
= Density of states2j 1 d
S (E)dE
2 2
mkN(k)2
S.E.A. Orrigo and H. Lenske, submitted to PLB (2008)
Neutron s.p. spectral functions in Neutron s.p. spectral functions in 99LiLi
Effects of the dynamical correlations (particle-hole coupling) due to the pairing field• The widths of the hole distributions (E<0) are due to the bound-continuum coupling
• The deeper-lying s-wave levels are coupled more efficiently to the particle continuum
• The 5/2+ d-wave strength is lowered into the bound state sector (intruder component)
• A small amount of 1/2+ and 3/2+ strengths is above the p½ peak
• Dramatic change in dynamics at the n-dripline: the level ordering is not determined by simple MF
E<0 hole sector
E>0 particle sector
S.E.A. Orrigo and H. Lenske, submitted to PLB (2008)
Partial wave cross sections Partial wave cross sections for elastic scattering for elastic scattering 99Li+n Li+n
Comparison: full HFB Gorkov-pairing – bare MF calculations• Pairing gives an attractive self-energy in the p-wave channels
→ 1/2– and 3/2– resonances at very low energy (E<<3MeV ~ threshold for DCP correlations)
• Slight attraction in the 1/2+ channel and repulsion for the d-waves
2j j2
2j 1 4(E) sin (E)2s 1 k
The structure results are used as input for transfer reaction calculations
S.E.A. Orrigo and H. Lenske, submitted to PLB (2008)
Continuum spectroscopy of Continuum spectroscopy of 1010Li by transfer reactionsLi by transfer reactions
Transfer reactionswell established tool for structural studies of bound and exotic nuclei Weakly-bound final state: prevalence of small momentum components the cross section maximum is at much lower incident energies
H. Lenske and G. Schrieder, Eur. Phys. J 2 (1998) 41
Single-nucleon transfer reactionsas a tool for continuum spectroscopy in exotic nuclei Study of the low-energy s.p. resonances in unbound systems also
Method based on a DWBA approach. Main innovations:to treat the case of unbound final states andto calculate the double differential cross section for one-neutron transfer The model is applied to the 9Li(d,p)10Li reaction to explore the structure of 10Li
10Li is neutron-unbound by 25 ± 15 keV
Why Why 1010Li?Li? Crucial for the comprehension of the structure of 11Li as a three body system
(11Li is a Borromean 2-n-halo nucleus) Information on the n-9Li interaction, important for the theoretical models of 11Li
Interest in the structure of 10Li itself: low-lying states are not yet well known• Ground state: p-wave or s1/2 virtual state at the n+9Li threshold?• 4 states are expected at low energy with J = 1−, 2− and 1+, 2+
(neutron in 2s1/2 or 1p1/2 unpaired 1p3/2 proton of the 9Li core)
• Two resonances seen at Ex ~ 250 and 500 keV; several resonances at higher Ex
D.R. Tilley et al., Nucl. Phys. A 745 (2004) 155 and refs. therein
Interest in the 9Li(d,p)10Li reaction in inverse kinematics: experiments at MSU @ 20 AMeV (P. Santi at al., Phys. Rev. C 67 (2003) 024606) resonance at ~ 350 keV with ~ 300 keV experiments at REX-ISOLDE @ 2.36 AMeV (H.B. Jeppesen et al., Phys. Lett. B 642 (2006) 449) resonance at ~ 380 keV with ~ 200 keV
Theory for transfer reactionsTheory for transfer reactions
Transfer reaction A(a,b)B (a = b+x, B = A+x) in a DWBA approach [Satchler]
• Optical model Hamiltonians and DW Schroedinger equations:
H = HA + Ha + K + U + V ( = a+A) ; H = HB + Hb + K + U + V = b+B)
(K + U – E) (±) (r, k) = 0 ( = )
• The optical model wave functions (±) (r, k) describe the elastic scattering determined
by the optical potentials U at the channel energies E= E – eA – ea
Hinterberger Menetd-potentials p-potentials NPA111(1968) PRC4(1971)
Residual interaction V (post)
chosen according to effective self-energy (full HFB Gorkov-pairing), it reproduces B.E., rM, rC of 9Li -36.14
for a fixed energy
• In the post representation for a stripping reaction in which x is transferred from a to B:
F = JB MB sb mb | V | JA MA sa ma =
=jl (Sjl)½ Rjl(rxA)(l s m – m | j )(sb s mb ma – mb | sa ma)(JA j MA MB – MA | JB MB)D(rxb) Ylm*( )
spectroscopic amplitude radial wave function for the transferred particle x
projectile internal function times x-b interaction potential
• Zero-Range Approximation:
D(rxb) = D0 (rx – rb) T = D0 (S)½ (–) | R(rx)Y*( ) (rx – rb) |
(+)
which contains dynamics and structure information
xr̂
xAr̂
Theory for transfer reactionsTheory for transfer reactions
• First order DWBA transition amplitude:
T = (–) | F |
(+)
F = bB|V|aA form factor 2
MmMmαβ
jβα
ααα
β22
βαj
βα
ββαα
k,kT 12J12j
1 kk
2π
μ μ
dΩdσ
Double differential cross section for one-nucleon transfer to unbound final states
Momentum distribution (Dynamics: Fourier transform
of the wave function) Spectral function (Structure: probability per energy for finding the particle in state ℓj at energy E)
Theory for transfer reactions Theory for transfer reactions to unbound statesto unbound statesTransfer into the continuum:The B = A+x final states are unbound against the reemission of the nucleon x (ex< 0) the overlap form factor oscillates at large distances the DWBA radial integrals converge very slowly
Vincent and Fortune:powerful method of contour integration in the complex radius plane to overcome the convergence problem C.M. Vincent and H.T. Fortune, PRC2(1970); PRC7(1973); PRC8(1973)
)N(q 2π D β22
0
θdΩ
dσ (E)S )D(q
dE dΩσd
j β
jβα
jβββ
βα2
S.E.A. Orrigo and H.Lenske,submitted to PLB (2008)
• p1/2 resonance at ER = 400 keV Mainly a potential resonance
• p3/2 resonance at ER = 850 keV Coupled-channels pairing resonance
New feature essential to describe dataobtained by adding a polarization repulsive surface potential (acting in E~250keV around ER) to reproduce the full HFB Gorkov-pairing results
• The theoretical results include the experimental energy resolution FWHM~250keV • Good agreement with data (shape and resonances position)
Spectroscopy of Spectroscopy of 1010Li = Li = 99Li+n at the continuum thresholdLi+n at the continuum threshold
0
2
4
6
8
10
12
14
16
0 0.2 0.4 0.6 0.8 1 1.2 1.4E [MeV]
d(9Li,10Li)pcm = [98°,134°]
Totaldata1/2+3/2-1/2-5/2+3/2+d
[m
b/M
eV]
dEAngle-integrated Angle-integrated
cross sectioncross section d(d(99Li,Li,1010Li)p Li)p
@ 2.36 AMeV@ 2.36 AMeV
S.E.A. Orrigo and H. Lenske, submitted to PLB (2008)
H.B. Jeppesen et al., PLB 642(2006)449ER ~ 380 keV, ~ 200 keV
Angular distributionsAngular distributions
• Good agreement with data (no scaling)
• The p1/2-wave is dominant
• As expected, transfer is favoured at low incident energies:
calculations @ 20 AMeV (MSU exp.) → transfer at ER(p1/2) is lowered by a factor of 26
• The measurement of angular distributions is important to identify the 10Li states (ℓ values)
Angular distributionsAngular distributions d(d(99Li,Li,1010Li)p Li)p
@ 2.36 AMeV@ 2.36 AMeV
S.E.A. Orrigo and H. Lenske, submitted to PLB (2008)
H.B. Jeppesen et al., PLB 642(2006)449ER ~ 380 keV, ~ 200 keV
0.1
1
10
100
0 20 40 60 80 100 120 140 160 180
Totaldata1/2+3/2-1/2-5/2+3/2+
d(9Li,10Li)p
cm [deg.]
d[mb/sr]d
Transfer Transfer 99Li(d,p)Li(d,p)1010Li @ 2.36 AMeV, before folding, Li @ 2.36 AMeV, before folding, cmcm =[98°,134°] =[98°,134°]
Elastic scattering n+Elastic scattering n+99Li (p-wave)Li (p-wave)
S.E.A. Orrigo and H. Lenske, submitted to PLB (2008)
0
2
4
6
8
10
12
0 0.2 0.4 0.6 0.8 1
p1/2p3/2d R[mb/
MeV]dE
E [MeV]
0
1000
2000
3000
4000
5000
6000
7000
8000
0 0.2 0.4 0.6 0.8 1
p1/2p3/2
E [MeV]
d E[mb/MeV]dE
• Same structure for elastic and transfer:
a physical resonance appears in both
ℓj(E) [°] → Sℓj (E)
Access to the spectroscopic
information by transfer
• However, in transfer there can be
not physical resonances also, due
only to the reaction dynamics part
E [MeV]0
20
40
60
80
100
120
140
0 0.2 0.4 0.6 0.8 1
Spectral distribution Spectral distribution ↔↔ properties of n- properties of n-99Li interactionLi interaction
S.E.A. Orrigo and H. Lenske, submitted to PLB (2008)
• Variations by ±10% of the potentialdiffuseness c and radius R
IVol = 486.62 (AMeV)·fm3 = constant
• p1/2-wave: ER, strongly sensitive to c
(asymptotic shape of potential, halo tail)
• Scattering length as = 1.69 fm
(c+10%)=1.68 fm, (c-10%)=1.72 fm(R+10%)=2.21 fm, (R-10%)=1.06 fm
• s1/2-wave: larger sensitivity to R
(no centrifugal barrier)
Information on the residual n-9Li interaction
c, Rc + 10%c – 10%R + 10%R – 10%
0
2000
4000
6000
8000
10000
12000
14000
16000
18000
0 0.2 0.4 0.6 0.8 1E [MeV]
Elastic scattering n+Elastic scattering n+99Li (pLi (p1/21/2-wave)-wave)
d E[mb/MeV]dE
SummarySummaryFano resonances can be expected to be of particular importance for the continuum dynamics of exotic nuclei
The coupled channels model extends the QPC into the continuum: the interference between open 1-QP and closed 3-QP ch. gives sharp and asymmetric resonances (→V13)
The calculations performed for 15C, 17C, 19C show increased effects of correlations
Exp. evidence of DCP correlations in the 15C spectra, qualitatively reproduced by theoretical calculations, and in the 11Be and 19O spectra
Transfer reactions are a powerful tool to do continuum spectroscopy in exotic nuclei
Innovations of the DWBA approach: to treat unbound final states and to calculate d2/ddE
Calculations performed for the d(9Li,10Li)p reaction at ELi = 2.36 and 20 AMeV10Li continuum: p1/2-resonance at ~400 keV and p3/2-pairing resonance at ~850 keV
in very good agreement with experimental data
Same behaviour of elastic and transfer: same structure S(E)
Correlation: spectral distributions ↔ n-9Li interaction (sensitivity to the halo tail)
Analogy: Configuration Mixing due to15C continuum = n+14C, BSEC = n+14C* core polarization (DCP)10Li continuum = n+9Li unbound, (particle-hole) pairing correlations (MF-level)
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Pairing in unbound nuclear states explored in terms of an extended MF approach
Paring effects may introduce pronounced structures and shifts in the low-energy continuum of all the channels
Configuration mixing acts at the MF level, but mechanisms similar to the mixing due to dynamical correlations
SummarySummary