A new approach to estimating the probability for delayed neutron emission
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A new approach to estimating the probability for delayed neutron emission E. A. McCutchan A.A. Sonzogni T.D. Johnson National Nuclear Data Center Brookhaven National Laboratory, NY USA
description
E. A. McCutchan A.A. Sonzogni T.D. Johnson National Nuclear Data Center Brookhaven National Laboratory, NY USA. A new approach to estimating the probability for delayed neutron emission. Outline. Motivation Traditional systematics A new parameterization A closer look. - PowerPoint PPT Presentation
Transcript of A new approach to estimating the probability for delayed neutron emission
A new approach to estimating the probability for delayed neutron emission
E. A. McCutchanA.A. SonzogniT.D. Johnson
National Nuclear Data CenterBrookhaven National Laboratory, NY USA
Outline
• Motivation
• Traditional systematics
• A new parameterization
• A closer look
-delayed neutrons and their use• Reactor control and
post-processing of fuel
• r-process nucleosynthesis and abundances
• Basic structure physics
214 nuclei with measured Pn values
http://www.nndc.bnl.gov/nudat2
Relevance of reliable systematics
Some terminology
AZ+1
Q
AZ
Sn
A-1Z+1
Qn
n
Pn : the probability to emit a
neutron following decay
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Kratz -Herrmann Formula (KHF)
𝑃𝑛≈𝑎 [𝑄 𝛽−𝑆𝑛
𝑄𝛽−𝐶 ]𝑏
Cut off parameter C (MeV)
𝐶=0𝐶=
13√𝐴
𝐶=26√𝐴
even-even
even-odd
odd-odd
Traditional systematic studies
K.-L. Kratz and G. Herrmann, Z. Phys. A 263, 435 (1973)
Two parameter fit with ‘a’ and ‘b’
Log-log plot gives straight linewith slope=b
B. Pfeiffer et al., Prog. Nucl. Energy 41, 39 (2002).
The standard for systematic studies
Linear regression
Weighted least-squares
a = 106(38)b = 5.5(6)
red 2 = 81
a = 119(42)b = 5.45(48)red 2 = 146
Audi and Meng (2011)
Effect of improved Q values
a = 106(38)b = 5.5(6)
red 2 = 81
Masses from :Audi and Wapstra (1995)
A better parameterization?Strength function Fermi integral
𝑃𝑛
𝑇1 /2𝑎(𝑄 𝛽𝑛)
𝑏
Applying same concept as KHF
A more compact trajectory
a = 0.0097(9)b = 4.87(7)red 2 = 35
a = 119(42)b = 5.45(48)red 2 = 146
Light fission fragment region
Heavy fission fragment region
a = 141(48)b = 5.08(37)red 2 = 78
a = 0.016(2)b = 4.55(13)red 2 = 55
A more compact trajectory
A surprising correlation
a = 45(6)b = 4.4(4)
red 2 = 280
a = 0.037(9)b = 4.11(9)red 2 = 87
Light nuclei, Z <26
A closer lookLight fission fragment region
• Very linear trend• Few outliers
100Rb102Rb
A closer lookHeavy fission fragment region
• Few outliers• Less linear trend• Possible shell
effects?
How do we do ??
KHF-2002: B. Pfeiffer et al., Prog. Nucl. Energy 41, 39 (2002).QRPA-1: P. Moller et al., Phys. Rev. C 67, 055802 (2003).
Another surprising correlation
P. Moller et al., Phys. Rev. C 67, 055802 (2003).
Summary• New prescription for systematics of Pn values
• Ratio of Pn to T1/2
• More compact trajectory
• Works across nuclear chart
• For the future• Extract information about strength function from slope ??
Relevance to ENSDF
• Some evaluators give Pfeiffer KHF results (2002Pf04) for cases where Pn has not been measured
• Should we replace with values from new systematics ?
Another surprising correlation
P. Moller et al., Phys. Rev. C 67, 055802 (2003).
