Publication Beamlines Strategic Pillar
Liana K.T. Stammers (2016). Geochemical Constraints of the Gold Mineralization Sources from the South Mine Complex and the Main/’04 Breaks, Macassa Mine, Kirkland Lake, Ontario. Supervisor: Banerjee, Neil R.; Van Loon, Lisa L.. ON, Canada: Western University. . CLS-APS, VESPERS Environment
Hong, Jason. K. (2012). Jarosite Occurrences in the MIL 03346 Nakhlite: Implications for Water on Mars. Supervisor: Cavell, Ronald; Gleeson, Sarah. Alberta, Canada: University of Alberta. https://doi.org/10.7939/R3RQ19. CLS-APS, VESPERS Environment
Maciag, Bryan J. (2022). GEOCHEMISTRY OF ARSENIC IN MAGMATIC SYSTEMS WITH SOME RESULTS FOR ANTIMONY. Dalhousie University. https://dalspace.library.dal.ca/bitstream/handle/10222/81893/BryanMaciag2022.pdf?sequence=6&isAllowed=y. CLS-APS Environment
Parigi, Roberta (2021). Nickel Isotope Geochemistry in Mine Waste System. Supervisor: Blowes, David. ON, Canada: University of Waterloo. http://hdl.handle.net/10012/16641. CLS-APS, CMCF-BM, HXMA, SXRMB Environment
Alana Ou Wang (2020). Application of Biochar to Stabilize Mercury in Riverbank Sediments and Floodplain Soils from South River, VA under Conditions Relevant to Riverine Environments. Supervisor: Ptacek, Carol. ON: University of Waterloo. http://hdl.handle.net/10012/15416. CLS-APS Environment
Nehzati, Susan (2019). Molecular Studies in Mercury Toxicity Using X-ray Absorption Spectroscopy and High Energy Resolution Fluorescence Detection X-ray Absorption Spectroscopy. Supervisor: George, Graham; Pickering, Ingrid. Saskatchewan, Canada: University of Saskatchewan. https://harvest.usask.ca/bitstream/handle/10388/12054/NEHZATI-DISSERTATION-2019.pdf?sequence=1. CLS-APS Environment
Qin, Zhixuan (2017). STRATEGIES FOR MANAGEMENT OF HIGH PHOSPHORUS AGRICULTURAL SOILS ON THE DELMARVA PENINSULA. University of Delaware. https://udspace.udel.edu/server/api/core/bitstreams/0325bbc1-6a22-49d8-8b65-572ec841b6bf/content. CLS-APS Environment
Radkova, Anezka Borcinova (2017). The influence of secondary mineral phase crystallization on antimony and arsenic mobility in mine drainage. Queen's University. https://qspace.library.queensu.ca/items/c4720a6c-c36c-475e-b00e-3612f58882c8. CLS-APS Environment
Petrash, Daniel A. (2016). The trace metal content of modern and ancient peritidal and shallow subtidal dolomites: significance and systematics. Supervisor: Konhauser, Kurt. AB CA: University of Alberta. https://era.library.ualberta.ca/files/c9019s2509#.WD2ty30SL0w. CLS-APS, MID-IR, VESPERS Environment
Lisa Van Loon; Neil Banerjee (2023). 14th Symposium on Mesozoic Terrestrial Ecosystems and Biota. Anatomical Record 306(S1) , 3-267. 10.1002/ar.25219. CLS-APS Environment
Liu, Peng; Ptacek, Carol; Blowes, David W.; Finfrock, Y. Zou (2020). Redox Mapping of Cr(VI) and Cr(III) in Biochar Particles Using Confocal Micro-X-Ray Fluorescence Imaging. . 10.46427/gold2020.1601. CLS-APS Environment
Arduini, Connor; Flynn, Trevor; Paetkau, Mark; Brewer, Sharon; Donkor, Kingsley et al. (2018). Synchrotron Characterization of Metal Distributions in Soils Collected in the Greater Kamloops Region, British Columbia, Canada. Microscopy and Microanalysis 24(S2) , 514-515. 10.1017/s1431927618014794. CLS-APS, IDEAS Environment
Dogan Paktunc, Michael C. Moncur, S. Jean Birks, John J. Gibson, Yi Yi (2015). Predicting the mobilization of dissolved metals, organics and gas Predicting the mobilization of dissolved metals, organics and gas Predicting the mobilization of dissolved metals, organics and gas Predicting the mobilization of dissolved metals, organics. Canada: Integrated Water Management, Alberta Innovates – Technology Futures, CANMET Mining and Mineral Scie. http://www.geoconvention.com/archives/2015/258_GC2015_Predicting_the_mobilization_of_dissolved_metals.pdf. CLS-APS Environment