Optimization of the dissolution of molybdenum disks. FY-16 results

Tkac, Peter; Rotsch, David A.; Chemerisov, Sergey D.; Bailey, James L.; Krebs, John F.; Vandegrift, George F.

doi:10.2172/1331320

Title: Optimization of the dissolution of molybdenum disks. FY-16 results

Technical Report · Thu Sep 01 00:00:00 EDT 2016

DOI:https://doi.org/10.2172/1331320· OSTI ID:1331320

Tkac, Peter ^[1]; Rotsch, David A. ^[1]; Chemerisov, Sergey D. ^[1]; Bailey, James L. ^[1]; Krebs, John F. ^[1]; Vandegrift, George F. ^[1]

Argonne National Lab. (ANL), Argonne, IL (United States)

Argonne National Laboratory is providing technical development assistance to NorthStar Medical Technologies LLC in its pursuit of two pathways for production of molybdenum-99: the ⁹⁸Mo(n,γ) ⁹⁹Mo reaction and the photonuclear reaction, ¹⁰⁰Mo(γ,n)⁹⁹Mo. Processing of irradiated targets, from either production mode, requires dissolution of the target material in H₂O₂ followed by a concentration step, addition of ferric ion to precipitate impurities, and conversion of the final solution to 5M potassium hydroxide solution of potassium molybdate. Currently, NorthStar is using pressed and sintered Mo disks as targets. Several options are being considered for the design of Mo targets for the production of ⁹⁹Mo using the (γ,n) reaction. In the current design, the target holder contains a series of sintered Mo disks lined up perpendicular to two incident electron beams, one entering from each side of the target stack. In this configuration, the front-most disks absorb most of the heat from the electron beam and need to be thinner to allow for better cooling, while the middle of the target can be thicker. Distribution of the total mass of Mo allows for larger masses of Mo material and thus larger production batches of ⁹⁹Mo. A limitation of the sintering approach is the production of very thin disks. Recent advances in 3D printing allow for much thinner target components can be achieved than when the traditional press-and-sinter approach is used. We have demonstrated that several factors can play important roles in dissolution behavior: particle size of Mo metal used for production of targets, sintering conditions, degree of open porosity, and thickness of the sintered Mo targets. Here we report experimental results from studies of small-scale dissolution of sintered Mo disks fabricated from various recycled and commercial Mo materials, and dissolution of 3D-printed Mo disks that were fabricated by Oak Ridge National Laboratory (ORNL). We also report on large-scale dissolution studies with 600 g batches of sintered Mo disks.

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Research Organization:: Argonne National Lab. (ANL), Argonne, IL (United States)

Sponsoring Organization:: USDOE National Nuclear Security Administration (NNSA), Office of Defense Nuclear Nonproliferation

DOE Contract Number:: AC02-06CH11357

OSTI ID:: 1331320

Report Number(s):: ANL/NE-16/28; 131127; TRN: US1700496

Country of Publication:: United States

Language:: English

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Related Subjects

38 RADIATION CHEMISTRY, RADIOCHEMISTRY, AND NUCLEAR CHEMISTRY
MOLYBDENUM 99
PRODUCTION
POTASSIUM COMPOUNDS
DISSOLUTION
FOILS
HYDROGEN PEROXIDE
POTASSIUM HYDROXIDES
SINTERED MATERIALS
IRRADIATION
MOLYBDATES
PARTICLE SIZE
IRON IONS
PRECIPITATION
THICKNESS
POROSITY
SINTERING

Title: Optimization of the dissolution of molybdenum disks. FY-16 results

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