Applications of ultra-high resolution microcalorimeter gamma-ray spectrometry

Katherine A. Schreiber; Katrina E. Koehler; Mark P. Croce; Emily N. Stark; Daniel G. McNeel; Matthew H. Carpenter; David J. Mercer; E. Paige Abel; Brian Archambault; Leah Arrigo; Grey Batie; Daniel T. Becker; Douglas A. Bennett; Brian M. Bucher; Stefania Dede; Joseph Fowler; Johnathon D. Gard; David Glasgow; K. C. Goetz; Craig Gray; Catalin Harabagiu; Jianwei Hu; Mark W. Keller; J. A. Ben Mates; Christine Mathew; Galen C. O’Neil; Nathan J. Ortiz; Luca Pagani; Bruce D. Pierson; Daniel R. Schmidt; Rico U. Schoenemann; Edward Seabury; Daniel S. Swetz; Joel N. Ullom; Sophie L. Weidenbenner; Ammon N. Williams

doi:10.3389/fnuen.2025.1654123

Applications of ultra-high resolution microcalorimeter gamma-ray spectrometry

Katherine A. Schreiber
, Katrina E. Koehler
, Mark P. Croce
, Emily N. Stark
, Daniel G. McNeel
, Matthew H. Carpenter
, David J. Mercer
, E. Paige Abel
, Brian Archambault
, Leah Arrigo
, Grey Batie
, Daniel T. Becker
, Douglas A. Bennett
, Brian M. Bucher
, Stefania Dede
, Joseph Fowler
, Johnathon D. Gard
, David Glasgow
, K. C. Goetz
, Craig Gray

Catalin Harabagiu, Jianwei Hu, Mark W. Keller, J. A. Ben Mates, Christine Mathew, Galen C. O’Neil, Nathan J. Ortiz, Luca Pagani, Bruce D. Pierson, Daniel R. Schmidt, Rico U. Schoenemann, Edward Seabury, Daniel S. Swetz, Joel N. Ullom, Sophie L. Weidenbenner, Ammon N. Williams

Research output: Contribution to journal › Article › peer-review

Abstract

Ultra-high energy resolution microcalorimeter gamma-ray spectroscopy—with energy resolution 5 to 10 times better than observed in spectra obtained by commercial-off-the-shelf high purity germanium detectors—is an enabling technology for ultra-precise isotope identification and quantification. Microcalorimeter gamma spectroscopy complements measurements requiring high-accuracy mass spectrometry, a costly, destructive analysis technique, and may offer benefits over mass spectrometry in the future. Microcalorimeter detectors are fabricated from superconducting materials and operate at ultra-low temperatures (<0.1 K), properties which permit measurement of spectra with peak full width half maximum (FWHM) of less than 100 eV at 100 keV. The microcalorimeter collaboration between Los Alamos National Laboratory, National Institute of Standards and Technology, and University of Colorado, Boulder has deployed three microcalorimeter gamma-ray spectrometers to nuclear facilities and analytical laboratories so far. These are the Spectrometer Optimized for Facility Integrated Applications (SOFIA), a portable system that can be moved to any facility, and two instruments called the High Efficiency and Resolution Microcalorimeter Spectrometers (HERMES) intended for permanent installation at Idaho National Laboratory and Pacific Northwest National Laboratory. Each spectrometer was customized to satisfy requirements for their specific applications. This work describes samples examined by microcalorimeter gamma-ray spectrometers, including recently irradiated materials, nuclear material from various stages of the fuel cycle, and medical isotope products. It also highlights useful signatures from actinide and fission product gamma-rays that are otherwise infeasible to observe or use for analysis without costly chemical separations and mass spectrometric assay. Microcalorimeter technology provides additional spectral signatures to existing techniques to better constrain the origin and intended use of nuclear and radioactive materials.

Original language	English
Article number	1654123
Journal	Frontiers in Nuclear Engineering
Volume	4
DOIs	https://doi.org/10.3389/fnuen.2025.1654123
State	Published - 2025

Funding

The author(s) declare that financial support was received for the research and/or publication of this article. Research presented in this article was supported by the U.S. Department of Energy Office of Nuclear Energy Material Protection, Accountancy, and Control Technology (MPACT) Program, Office of Nuclear Energy Advanced Reactor Safeguards and Security (ARSS) Program, and the National Nuclear Security Administration Office of Defense Nuclear Nonproliferation Research and Development.

Keywords

gamma-ray spectrometry
isotope identification
microcalorimeter spectrometer
nuclear forensics and safeguards
nuclear fuel cycle

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10.3389/fnuen.2025.1654123

Cite this

Schreiber, K. A., Koehler, K. E., Croce, M. P., Stark, E. N., McNeel, D. G., Carpenter, M. H., Mercer, D. J., Abel, E. P., Archambault, B., Arrigo, L., Batie, G., Becker, D. T., Bennett, D. A., Bucher, B. M., Dede, S., Fowler, J., Gard, J. D., Glasgow, D., Goetz, K. C., ... Williams, A. N. (2025). Applications of ultra-high resolution microcalorimeter gamma-ray spectrometry. Frontiers in Nuclear Engineering, 4, Article 1654123. https://doi.org/10.3389/fnuen.2025.1654123

@article{59334c00410746c6bc9dc31f6b1ea43a,

title = "Applications of ultra-high resolution microcalorimeter gamma-ray spectrometry",

abstract = "Ultra-high energy resolution microcalorimeter gamma-ray spectroscopy—with energy resolution 5 to 10 times better than observed in spectra obtained by commercial-off-the-shelf high purity germanium detectors—is an enabling technology for ultra-precise isotope identification and quantification. Microcalorimeter gamma spectroscopy complements measurements requiring high-accuracy mass spectrometry, a costly, destructive analysis technique, and may offer benefits over mass spectrometry in the future. Microcalorimeter detectors are fabricated from superconducting materials and operate at ultra-low temperatures (<0.1 K), properties which permit measurement of spectra with peak full width half maximum (FWHM) of less than 100 eV at 100 keV. The microcalorimeter collaboration between Los Alamos National Laboratory, National Institute of Standards and Technology, and University of Colorado, Boulder has deployed three microcalorimeter gamma-ray spectrometers to nuclear facilities and analytical laboratories so far. These are the Spectrometer Optimized for Facility Integrated Applications (SOFIA), a portable system that can be moved to any facility, and two instruments called the High Efficiency and Resolution Microcalorimeter Spectrometers (HERMES) intended for permanent installation at Idaho National Laboratory and Pacific Northwest National Laboratory. Each spectrometer was customized to satisfy requirements for their specific applications. This work describes samples examined by microcalorimeter gamma-ray spectrometers, including recently irradiated materials, nuclear material from various stages of the fuel cycle, and medical isotope products. It also highlights useful signatures from actinide and fission product gamma-rays that are otherwise infeasible to observe or use for analysis without costly chemical separations and mass spectrometric assay. Microcalorimeter technology provides additional spectral signatures to existing techniques to better constrain the origin and intended use of nuclear and radioactive materials.",

keywords = "gamma-ray spectrometry, isotope identification, microcalorimeter spectrometer, nuclear forensics and safeguards, nuclear fuel cycle",

author = "Schreiber, \{Katherine A.\} and Koehler, \{Katrina E.\} and Croce, \{Mark P.\} and Stark, \{Emily N.\} and McNeel, \{Daniel G.\} and Carpenter, \{Matthew H.\} and Mercer, \{David J.\} and Abel, \{E. Paige\} and Brian Archambault and Leah Arrigo and Grey Batie and Becker, \{Daniel T.\} and Bennett, \{Douglas A.\} and Bucher, \{Brian M.\} and Stefania Dede and Joseph Fowler and Gard, \{Johnathon D.\} and David Glasgow and Goetz, \{K. C.\} and Craig Gray and Catalin Harabagiu and Jianwei Hu and Keller, \{Mark W.\} and \{Ben Mates\}, \{J. A.\} and Christine Mathew and O{\textquoteright}Neil, \{Galen C.\} and Ortiz, \{Nathan J.\} and Luca Pagani and Pierson, \{Bruce D.\} and Schmidt, \{Daniel R.\} and Schoenemann, \{Rico U.\} and Edward Seabury and Swetz, \{Daniel S.\} and Ullom, \{Joel N.\} and Weidenbenner, \{Sophie L.\} and Williams, \{Ammon N.\}",

note = "Publisher Copyright: Copyright {\textcopyright} 2025 Schreiber, Koehler, Croce, Stark, McNeel, Carpenter, Mercer, Abel, Archambault, Arrigo, Batie, Becker, Bennett, Bucher, Dede, Fowler, Gard, Glasgow, Goetz, Gray, Harabagiu, Hu, Keller, Ben Mates, Mathew, O{\textquoteright}Neil, Ortiz, Pagani, Pierson, Schmidt, Schoenemann, Seabury, Swetz, Ullom, Weidenbenner and Williams.",

year = "2025",

doi = "10.3389/fnuen.2025.1654123",

language = "English",

volume = "4",

journal = "Frontiers in Nuclear Engineering",

issn = "2813-3412",

publisher = "Frontiers Media",

}

Schreiber, KA, Koehler, KE, Croce, MP, Stark, EN, McNeel, DG, Carpenter, MH, Mercer, DJ, Abel, EP, Archambault, B, Arrigo, L, Batie, G, Becker, DT, Bennett, DA, Bucher, BM, Dede, S, Fowler, J, Gard, JD, Glasgow, D , Goetz, KC, Gray, C, Harabagiu, C, Hu, J, Keller, MW, Ben Mates, JA, Mathew, C, O’Neil, GC, Ortiz, NJ, Pagani, L, Pierson, BD, Schmidt, DR, Schoenemann, RU, Seabury, E, Swetz, DS, Ullom, JN, Weidenbenner, SL & Williams, AN 2025, 'Applications of ultra-high resolution microcalorimeter gamma-ray spectrometry', Frontiers in Nuclear Engineering, vol. 4, 1654123. https://doi.org/10.3389/fnuen.2025.1654123

TY - JOUR

T1 - Applications of ultra-high resolution microcalorimeter gamma-ray spectrometry

AU - Schreiber, Katherine A.

AU - Koehler, Katrina E.

AU - Croce, Mark P.

AU - Stark, Emily N.

AU - McNeel, Daniel G.

AU - Carpenter, Matthew H.

AU - Mercer, David J.

AU - Abel, E. Paige

AU - Archambault, Brian

AU - Arrigo, Leah

AU - Batie, Grey

AU - Becker, Daniel T.

AU - Bennett, Douglas A.

AU - Bucher, Brian M.

AU - Dede, Stefania

AU - Fowler, Joseph

AU - Gard, Johnathon D.

AU - Glasgow, David

AU - Goetz, K. C.

AU - Gray, Craig

AU - Harabagiu, Catalin

AU - Hu, Jianwei

AU - Keller, Mark W.

AU - Ben Mates, J. A.

AU - Mathew, Christine

AU - O’Neil, Galen C.

AU - Ortiz, Nathan J.

AU - Pagani, Luca

AU - Pierson, Bruce D.

AU - Schmidt, Daniel R.

AU - Schoenemann, Rico U.

AU - Seabury, Edward

AU - Swetz, Daniel S.

AU - Ullom, Joel N.

AU - Weidenbenner, Sophie L.

AU - Williams, Ammon N.

N1 - Publisher Copyright: Copyright © 2025 Schreiber, Koehler, Croce, Stark, McNeel, Carpenter, Mercer, Abel, Archambault, Arrigo, Batie, Becker, Bennett, Bucher, Dede, Fowler, Gard, Glasgow, Goetz, Gray, Harabagiu, Hu, Keller, Ben Mates, Mathew, O’Neil, Ortiz, Pagani, Pierson, Schmidt, Schoenemann, Seabury, Swetz, Ullom, Weidenbenner and Williams.

PY - 2025

Y1 - 2025

N2 - Ultra-high energy resolution microcalorimeter gamma-ray spectroscopy—with energy resolution 5 to 10 times better than observed in spectra obtained by commercial-off-the-shelf high purity germanium detectors—is an enabling technology for ultra-precise isotope identification and quantification. Microcalorimeter gamma spectroscopy complements measurements requiring high-accuracy mass spectrometry, a costly, destructive analysis technique, and may offer benefits over mass spectrometry in the future. Microcalorimeter detectors are fabricated from superconducting materials and operate at ultra-low temperatures (<0.1 K), properties which permit measurement of spectra with peak full width half maximum (FWHM) of less than 100 eV at 100 keV. The microcalorimeter collaboration between Los Alamos National Laboratory, National Institute of Standards and Technology, and University of Colorado, Boulder has deployed three microcalorimeter gamma-ray spectrometers to nuclear facilities and analytical laboratories so far. These are the Spectrometer Optimized for Facility Integrated Applications (SOFIA), a portable system that can be moved to any facility, and two instruments called the High Efficiency and Resolution Microcalorimeter Spectrometers (HERMES) intended for permanent installation at Idaho National Laboratory and Pacific Northwest National Laboratory. Each spectrometer was customized to satisfy requirements for their specific applications. This work describes samples examined by microcalorimeter gamma-ray spectrometers, including recently irradiated materials, nuclear material from various stages of the fuel cycle, and medical isotope products. It also highlights useful signatures from actinide and fission product gamma-rays that are otherwise infeasible to observe or use for analysis without costly chemical separations and mass spectrometric assay. Microcalorimeter technology provides additional spectral signatures to existing techniques to better constrain the origin and intended use of nuclear and radioactive materials.

AB - Ultra-high energy resolution microcalorimeter gamma-ray spectroscopy—with energy resolution 5 to 10 times better than observed in spectra obtained by commercial-off-the-shelf high purity germanium detectors—is an enabling technology for ultra-precise isotope identification and quantification. Microcalorimeter gamma spectroscopy complements measurements requiring high-accuracy mass spectrometry, a costly, destructive analysis technique, and may offer benefits over mass spectrometry in the future. Microcalorimeter detectors are fabricated from superconducting materials and operate at ultra-low temperatures (<0.1 K), properties which permit measurement of spectra with peak full width half maximum (FWHM) of less than 100 eV at 100 keV. The microcalorimeter collaboration between Los Alamos National Laboratory, National Institute of Standards and Technology, and University of Colorado, Boulder has deployed three microcalorimeter gamma-ray spectrometers to nuclear facilities and analytical laboratories so far. These are the Spectrometer Optimized for Facility Integrated Applications (SOFIA), a portable system that can be moved to any facility, and two instruments called the High Efficiency and Resolution Microcalorimeter Spectrometers (HERMES) intended for permanent installation at Idaho National Laboratory and Pacific Northwest National Laboratory. Each spectrometer was customized to satisfy requirements for their specific applications. This work describes samples examined by microcalorimeter gamma-ray spectrometers, including recently irradiated materials, nuclear material from various stages of the fuel cycle, and medical isotope products. It also highlights useful signatures from actinide and fission product gamma-rays that are otherwise infeasible to observe or use for analysis without costly chemical separations and mass spectrometric assay. Microcalorimeter technology provides additional spectral signatures to existing techniques to better constrain the origin and intended use of nuclear and radioactive materials.

KW - gamma-ray spectrometry

KW - isotope identification

KW - microcalorimeter spectrometer

KW - nuclear forensics and safeguards

KW - nuclear fuel cycle

UR - https://www.scopus.com/pages/publications/105017079294

U2 - 10.3389/fnuen.2025.1654123

DO - 10.3389/fnuen.2025.1654123

M3 - Article

AN - SCOPUS:105017079294

SN - 2813-3412

VL - 4

JO - Frontiers in Nuclear Engineering

JF - Frontiers in Nuclear Engineering

M1 - 1654123

ER -

Applications of ultra-high resolution microcalorimeter gamma-ray spectrometry

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Keywords

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