Nuclear Level Density

1. What we know, what we do not know, and what we want to know

2. Experimental techniques to study level densities, what has been done until now

3. What kind of experiments we need to develop in the future

Excitation energy

Leve

l den

sity

Bn

Level density is knownfor most of the stable nuclei

Level density is unknown formost of the nuclei

Traditionally, for most of the nuclei, the level density is estimated on the basis of experimental information from low-lying discrete levels and neutron resonance spacing

E

How is nuclear level density estimated ?

Nuclear level density models

Fermi-gas model : comes from consideration of noninteracting fermi-particles moving in a common potential

Constant temperature model : does not have a theoretical justification for nuclei (only for classical ideal gas)

Microscopical models : calculations based on different representation of nuclear potentials plus collective effects

Additional problems:

1. spin cutoff parameter at neutron binding energy is not known2. ratio of levels with negative and positive parities is not known3. possible deviations of the shape of real level density from model

functions assumed for interpolation

might lead to

extra uncertainties of total level densities

We need to develop some experimental techniques capable to measure the precise energy dependence of TOTAL level densities in the whole

excitation region

The level density from particle evaporation spectra of compound nuclear reactions

The concept:

dET

EETEEd

idi

fdC

)()'()(~)(

*

The problem :

Make sure that the compound reaction mechanism dominates.

Possible solutions:

1. Select appropriate reactions (beam species, energies, targets).2. Measure angular distributions to study reaction mechanism 3. Compare reactions with different targets and incoming species leading to the same final nuclei

Compoundnulceus

+

dEEEETEd exf )()(~)(

(Wikipedia)Maxwell–Boltzmann distribution

(Hauser-Feshbach theory)

Early works on level densities from evaporation spectra:

H. Vonach (Vienna, Austria):S.Grimes (OU):B.Zhuravlev (Obninsk, Russia):

(n,p); (n,a); (a,n) (p,n)

Advantage: The compound nuclear mechanism dominates.Drawback: Negative Q-values of reactions that require higher energy beams if we want to measure level density at higherexcitation energies. Pre-equilibrium processes become important !

Other options:

d, 3He, 12C, 6Li, 7Li … beams Q-reactions are positive (for some of them), less beam energy is needed Smaller E/A which decreases pre-equilibrium contributions.

Beam energies: up to 15 MeV

Particle evaporation measurements at Edwards Lab of Ohio University

3He 58Fe59Cod+ +

61Ni

np

α

60Ni60Co

57Fe

Compound nucleus

Make sure that features of spectra of outgoing particles are determined by internal nuclear properties of a compound nucleus !!!

Compound nucleus formation

6Li 55Mn+

11 MeV

15 MeV

7.5 MeV

d, 3He

neutronsNE213

Flight path 8m

target

Swinger facilityat Edwards Lab. Ohio University

beamTarget

Si

Si

Si

SiSi

SiSi

Si

Si

Si

2m flight path

Scheme of experimental set-up for charge-particle spectra measurementsEdward’s Accelerator Lab, Ohio University

Experimental level densities from (d,n) reactions measured at Edwards Lab. of Ohio University

Testing the level density with 27Al(d,n)28Si

0 2 4 6 8 10 12 14 16

10-2

10-1

100

101

102

Experiment, from 27Al(d,n)28Si reaction From counting of discrete levels

Leve

l densi

ty, 1

/MeV

Excitation energy, MeV

Level density of 28Si

Excitation energy, MeV

Level densi

ty,

1/M

eV

Points are from our experiment, red line the the Fermi-gas model with parameters found from the fit to discrete levels and neutron resonance spacing, black line is the Fermi-gas model fit to experimental points

0 5 10 15 20 2510-6

10-5

10-4

10-3

10-2

10-1

100

101

102

103

experiment Fermi-gas Constant Temperature

Cro

ss s

ect

ion, m

b/M

eV

Proton energy, MeV

6Li+55Mn ---> 60Co+p

0 5 10 15 20 2510-7

10-6

10-5

10-4

10-3

10-2

10-1

100

101

102

103

104

105

0 5 10 15 20 2510-7

103

0 5 10 15 20101

102

103

104

105

106

107

108

109

Cro

ss s

ect

ion, m

b/M

eV

Neutron energy, MeV

Proton energy, MeV

0 5 10 15 20100

101

102

103

104

105

106

107

108

109

Leve

l densi

ty, M

eV

-1

Exciation energy, MeV

60Co60Co

Simulation with Empire reaction code

6Li+55Mn60Ni+n

60Co+p

Level density off stability line

S.I. Al-Quraishi, S.Grimes et al, Phys.Rev.C63, 065803

Possible theoretical explanation could be that the level density is lower off stability line because levels which have too wide width should not be counted in compound nuclear reactions because no equilibration can take place.

What is next ?

Study evaporation spectra from ion induced reactions.

Advantages:

• Lower E/A compared to nucleon induced reaction (n,p,a) that makes the compound nuclear mechanism dominant.

• Larger energy interval for outgoing particles allowing us to study level density in a larger excitation energy range ( at least up to 20-25 MeV).

• Possibility to study nuclei off stability line (proton rich nuclei).

GARFIELD is the new generation state of the art spectrometer to study nuclear level density and physics of compound nuclear reactions

D.R. Chakrabarty et alNuclear Physics A 712 (2002) 23–36