Deciphering Nb 98 ß decay with the Modular Total Absorption Spectrometer at ORNL

Authors

B. C. Rasco, ORNL Physics Division
K. P. Rykaczewski, ORNL Physics Division
A. Fijalkowska, University of Warsaw
M. Karny, University of Warsaw
M. Wolinska-Cichocka, ORNL Physics Division
R. K. Grzywacz, ORNL Physics Division
D. W. Stracener, ORNL Physics Division
E. F. Zganjar, Louisiana State University
J. C. Batchelder, Oak Ridge National Laboratory
J. C. Blackmon, Louisiana State University
N. T. Brewer, ORNL Physics Division
M. P. Cooper, The University of Tennessee, Knoxville
K. C. Goetz, The University of Tennessee, Knoxville
J. W. Johnson, ORNL Physics Division
T. King, ORNL Physics Division
A. Laminack, ORNL Physics Division
J. T. Matta, ORNL Physics Division
K. Miernik, University of Warsaw
M. Madurga, The University of Tennessee, Knoxville
D. Miller, The University of Tennessee, Knoxville
M. M. Rajabali, Tennessee Technological University
T. Ruland, Louisiana State University
P. Shuai, ORNL Physics Division
M. Stepaniuk, University of Warsaw
J. Winger, University of Mississippi

Document Type

Article

Publication Date

6-1-2022

Abstract

Background: An assessment done under the auspices of the Organization for Economic Co-operation and Developement Nuclear Energy Agency (OECD-NEA) in 2007 suggested that the ß decays of many abundantly produced fission products in nuclear reactors may be incomplete. In this assessment, the fission product Nb98 was assigned the highest priority for study by total absorption spectroscopy due to its large cumulative fission branching fraction and because the ß-decay data from several experiments are discrepant. Purpose: To obtain the complete ß-decay feeding pattern of Nb98 and determine the impact on the average ? energy per Nb98ß decay and ?¯e emission calculations. The complete 98Nb ß-decay feeding pattern includes ground-state to ground-state ß feeding and direct ß feeding to the 0+ first-excited state (both have no associated ? rays), and the ground-state to excited-state ß transitions followed by ? transitions to the ground state of the daughter nucleus, Mo98. Method: The complete ß-decay intensities of Nb98 were measured with the Modular Total Absorption Spectrometer at Oak Ridge National Laboratory (ORNL). The Nb98 was produced by the ß decay of mass 98 fission fragments at ORNL's On-Line Test Facility (OLTF) using proton-induced fission of U238. Results: We find that changes to the current ENSDF assessment of Nb98ß-decay intensity are required. We report improved uncertainties for the ß-decay feeding values and report new ß feedings to high-energy levels in Mo98. Conclusions: A more complete Nb98ß-feeding pattern with improved accuracy and precision is offered. The impacts of the measured changes to the Nb98ß-feeding pattern on both reactor decay heat calculations and predicted detection rates of reactor ?¯e are presented. The Modular Total Absorption Spectrometer measurements of Nb98 demonstrate the importance of reexamining and remeasuring complex ß-decaying fission products with total absorption spectroscopy, including nuclei very near ß stability.

Publication Source (Journal or Book title)

Physical Review C

Recommended Citation

Rasco, B., Rykaczewski, K., Fijalkowska, A., Karny, M., Wolinska-Cichocka, M., Grzywacz, R., Stracener, D., Zganjar, E., Batchelder, J., Blackmon, J., Brewer, N., Cooper, M., Goetz, K., Johnson, J., King, T., Laminack, A., Matta, J., Miernik, K., Madurga, M., Miller, D., Rajabali, M., Ruland, T., Shuai, P., Stepaniuk, M., & Winger, J. (2022). Deciphering Nb 98 ß decay with the Modular Total Absorption Spectrometer at ORNL. Physical Review C, 105 (6) https://doi.org/10.1103/PhysRevC.105.064301