8/18/2010Robert Fairchild LBNL Bevatron Characterization of Activation Products Robert Fairchild Lawrence Berkeley National Lab Radiation Protection Group.

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Presentation transcript:

8/18/2010Robert Fairchild LBNL Bevatron Characterization of Activation Products Robert Fairchild Lawrence Berkeley National Lab Radiation Protection Group ASW-2010 Lesson Learned Breakout Session

8/18/2010Robert Fairchild Bevatron History 1.Operated from 1954 to Accelerated primarily protons (6.2 GeV) in the early years and switched to heavy ions in later years (mid-1960s) including 238U (2.1 GeV/amu). 3.Lots of Depleted Uranium used as shielding, beam stops, etc. 4.Activation of concrete shielding and metal

8/18/2010Robert Fairchild Modeling the Activation Production Induced Radioactivity in Bevatron Concrete Radiation Shield Blocks, Moeller and Donahue, July Modeled the neutron production and depth of maximum thermal flux using LAHET Code System (Monte-Carlo based). 2.Neutron production and transport modeled 10 GeV to thermal energies 3.Neutron production was modeled by simulating 4.0 GeV protons on iron target (magnets) 4.Considered materials/construction: o Magnet Steel 2.5 to 4.0 feet thick o Concrete wall shielding 5 to 10 feet thick and stacked up to 16 feet high. No roof shield initially o In 1962 upgraded to 10 feet thick at all wall locations and added 7-feet thick roof shield. o Used heavy concrete (225 lbs/ft3) for center course of walls and normal density (150 lbs/ft3) on roof. o Target locations (in ring until ~1963, then External Proton Beam (EPB) hall)

8/18/2010Robert Fairchild Activation Primarily from incident beam on magnets, targets, beam dumps, plunging devices, and beam line apparatus creating prompt radiation. Produced by spallation and low energy neutron absorption. Emit primarily gamma-rays, but ~ 75% emit beta. Due to self shielding, survey method is by detecting gamma-rays. Most activation produced during proton runs and prior to 1974, thus 36 years have passed. Only long-lived isotopes are of concern.

8/18/2010Robert Fairchild Isotopes of Concern 15 long-lived isotopes could have been produced by spallation. Only 4 emit gamma-rays, but production rate is about the same (~ 1 mb), thus the gamma-emitters can be used as surrogates for the others Al (1.809, 0.511, …MeV) 7.3E5 years Na (1.275, 0.511, …MeV) 2.6 years Mn (0.835 MeV) 312 days Ti (0.078, MeV) 52 years 4 long lived isotopes could have been produced through thermal neutron capture Co (1.33, 1.17 MeV) 5.3 years Eu (0.121, 1.41, …MeV) 13.5 years Eu (0.123, 1.27, …MeV) 8.6 years Cs (0.658, 0.089, …MeV) 2.1 years

8/18/2010Robert Fairchild What about 55Fe? 55 Fe was not modeled by Moeller and Donahue, but we can determine the 55Fe activity by using surrogates. Thermal neutron capture cross section o 151 Eu is 5900 barn and 54 Fe is 2.32 barn (Warner, et al., 2010), thus ~2500:1 Eu to Fe Abundance in concrete (Hampel, et al., 2002) o 54 Fe 5.0 mg/kg and 151 Eu mg/kg, thus ~2500:1 Fe to Eu Half-Life o 55 Fe (2.7 years) and 152 Eu (13.5 years), thus 5:1 activity ratio 55 Fe to 152 Eu Potential production stopped in times less 55 Fe in the concrete today than 152 Eu

8/18/2010Robert Fairchild Conclusion of Moeller and Donahue paper 1.Peak activation production is at depth of 6 cm, but essentially uniform from surface of concrete to 16 cm (6.5 inches). 2.This showed good correlation to results from Princeton- Pennsylvania Accelerator concrete analysis.

8/18/2010Robert Fairchild Early Block Removal Process (EPB Hall Deconstruction) 1.Over 1000 blocks from the EPB hall were characterized 2.Survey each face with NaI to locate hottest spot 3.Performed in-situ gamma-ray spectroscopy on hottest spot on each block 4.Process took approximately 2 years 5.Approximately 1/3 were determined to be activated above the 1 pCi/g waste determination MDC and disposed of as radioactive waste.

8/18/2010Robert Fairchild Phase 2 Removal of ~75 upper-tier roof blocks (early 2004) 1.Early process was too long and labor intensive. 2.Performed measurements to correlate a 3x3 NaI to HPGe measurements 3.Established procedure to survey the blocks using 3x3 NaI and ensure 1 pCi/g MDC. 4.If a block failed the NaI survey process, then an in-situ HPGe analysis would be made. 5.Approximately a dozen blocks failed the NaI survey, but were released following further HPGe analysis.

8/18/2010Robert Fairchild Reconnaissance Level Characterization (late 2006) Due to earlier surveys and sampling of shield blocks, characterization of the shield blocks was not included in the scope of the Reconnaissance Level Characterization.

8/18/2010Robert Fairchild Phase 3 Demolition (RFP 2008) Survey remaining shield blocks comprising lower tier roof blocks, original inner layer wall blocks and outer layer added in Approximately 800 blocks in all. Naturally occurring isotope concentrations are not as homogenous as in upper tier roof block, so determined new MDC for 3x3 NaI to be ~2 pCi/g based on many measurements of non-impacted concrete. Obtained site office concurrence for new measurement sensitivity requirement Planned to use same survey protocol as upper-tier roof blocks. Early project planners estimated the number of blocks that would be activated based on percentage of blocks from EPB hall that were disposed of as radioactive waste.

8/18/2010Robert Fairchild Lower-Tier Roof Blocks Reference block selected from area that was least likely to contain activation. Characterized by HPGe and verified to be free of activation down to a measurement sensitivity of approximately 1 pCi/g, which was below the agreed upon 2 pCi/g sensitivity level. Began surveys of roof blocks, failed a few and cleared a few. Subcontractor decided to core the elevated area of a failed block and send it to an offsite lab for analysis. The subcontractor also decided to core the reference block.

8/18/2010Robert Fairchild Reference Block Coring Below MDC for all suspect isotopes except 152Eu 152Eu at pCi/g with an error of pCi/g and MDC of 0.14 pCi/g The cleanest remaining lower tier roof block contained activation products.

8/18/2010Robert Fairchild Path Forward 1.Pursue Authorized Release Limit or Not? 2.How would California Executive Order D affect decision? 3.If granted authorize release, could we rubbelize and reuse in CA? 4.Cost vs. benefit analysis

8/18/2010Robert Fairchild Final Decision The Bevatron Project Management determined that there was no cost benefit to pursuing an authorized release. All blocks and concrete that were within direct line-of-sight to the beam line would be disposed of as radioactive waste.

8/18/2010Robert Fairchild Outer Wall Blocks A reference block for the outer wall blocks was selected and analyzed by coring sample to a sample sensitivity level of 0.2 pCi/g and verified to be free of activation. All remaining outer wall blocks were then surveyed using the 3x3 NaI process. Like the upper tier roof blocks, all outer wall block were determined to be free of activation.

8/18/2010Robert Fairchild Lessons Learned Don’t assume anything during your planning phase (samples are cheap). Ensure sub-contractors clearly communicate with Site. In today’s climate, consider pursuing authorized release limits as soon as characterization results are available. No disposal or reuse path for known rad-added in CA.

8/18/2010Robert Fairchild

8/18/2010Robert Fairchild

8/18/2010Robert Fairchild

8/18/2010Robert Fairchild QUESTIONS?