Browsing by Author "Doran, G"
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- ItemRadionuclide bioaccumulation in trees at an Australian legacy low-level waste site: concentration patterns in branches and foliage(American Nuclear Society, 2014-08-24) Wilsher, KL; Johansen, MP; Harrison, JJ; Payne, TE; Howitt, JA; Doran, G; Child, DP; Hotchkis, MAC; Thiruvoth, S; Mokhber-Shahin, L; Twining, JR; Vardanega, CR; Wong, HKYNot available
- ItemRadionuclide bioaccumulation patterns in vegetation at a legacy low-level waste site(Australian Nuclear Science and Technology Organisation, 2012-10-16) Wilsher, KL; Johansen, MP; Howitt, JA; Doran, G; Twining, JR; Child, DP; Dodson, JR; Dore, MJ; Harrison, JJ; Hotchkis, MAC; Mokhber-Shahin, L; Payne, TE; Thiruvoth, S; Wong, HKYThis study focuses on uptake of radionuclides (RN) into trees at a legacy low level radioactive waste site (the Little Forest Burial Ground (LFBG) near Lucas Heights in southern Sydney). Tree species included: Acacia longifolia longifolia; Syncarpia glomulifera; Eucalyptus paniculate; Leptospermum polygalifolium; and Banksia serrata. Branches – (wood and foliage) were sampled, and soil cores were collected around each tree. Analytical techniques included Inductively Coupled Plasma Atomic Emission Spectrometry and Mass Spectrometry, alpha and gamma spectrometry, Accelerator Mass Spectrometry and Cerenkov counting. Anthropogenic RN measured in trees and soils were 90Sr, 137Cs, 233U, 239+240Pu and 241Am. Median concentrations of RN in trees growing on, or near, the trenches (90Sr - 9.855 Bq/kg, 137Cs - 0.220 Bq/kg, 239+240Pu - 0.004 Bq/kg) were significantly higher than background trees (90Sr – 0.001 Bq/kg, 137Cs – n.d., 239+240Pu - 0.002 Bq/kg). Most trees had higher levels in foliage compared to wood. However; there was large variation among branches within the same tree. Uptake of radionuclides was quantified by the concentration ratio (CR), defined as average concentration in the tree to that of the surrounding soil. CR’s for trees growing around the trenches were an order of magnitude higher than for background trees, which is attributed to the trees taking up radionuclides directly from the subsurface. Our results better quantify the bio-available fraction of radionuclides in the environment at the LFBG, and reveal that site trees are bio-monitors of multiple radionuclides sourced from the sub-surface wastes.