Daly, Katelynn (2023). Synchrotron-based investigation of nanoscaled water-splitting electrocatalysts for clean energy storage. Supervisor: Trudel, Simon. Alberta, Canada: University of Calgary. https://hdl.handle.net/1880/117010. |
HXMA, SGM, SXRMB |
Doctoral Thesis |
Materials |
Daly, Katelynn (2023). Synchrotron-based investigation of nanoscaled water-splitting electrocatalysts for clean energy storage. Supervisor: Trudel, Simon. Alberta, Canada: University of Calgary. https://hdl.handle.net/1880/117010. |
HXMA, SGM, SXRMB |
Doctoral Thesis |
Materials |
Pierce, Caroline Emily (2023). The Effect of Climate Change on Mercury in Boreal Peatlands. Supervisor: Toner, Brandy; Nater, Edward. Minnesota, United States: University of Minnesota. http://cyber.usask.ca/login?url=https://www.proquest.com/dissertations-theses/effect-climate-change-on-mercury-boreal-peatlands/docview/2878191754/se-2?accountid=14739. |
SXRMB |
Doctoral Thesis |
Environment |
Daly, Katelynn (2023). Synchrotron-based investigation of nanoscaled water-splitting electrocatalysts for clean energy storage. Supervisor: Trudel, Simon. Alberta, Canada: University of Calgary. https://hdl.handle.net/1880/117010. |
HXMA, SGM, SXRMB |
Doctoral Thesis |
Materials |
Zhu, Peng (2023). Catalysts Design and Reactor Engineering for Electrochemical CO2 Capture and Utilization. Supervisor: Wang, Haotian. Texas, USA: Rice University. https://hdl.handle.net/1911/115247. |
SXRMB |
Doctoral Thesis |
Materials |
Valeria Alvarado González (2023). Synthesis and evaluation of graphenesupported catalysts for its potential use in aquaprocessing of heavy crude oil”. Supervisor: Escobar Barrios, Vladimir Alonso. San Luis Potosi, Mexico: Instituto Potosino de Investigación Científica Tecnológica. http://hdl.handle.net/11627/6472. |
SXRMB |
Doctoral Thesis |
Materials |
Uwanyirigira, Janviere (2023). Integrated Synchrotron Approaches to Characterize Organic Matter-Iron Phases Relevant to Passive Mine Waste Remediation Systems. Supervisor: McBeth, Joyce. Saskatchewan, Canada: University of Saskatchewan. https://hdl.handle.net/10388/14832. |
BIOXAS-IMAGING, BIOXAS-MAIN, BXDS-WHE, CMCF-BM, SGM, SXRMB |
Masters Thesis |
Environment |
Uwanyirigira, Janviere (2023). Integrated Synchrotron Approaches to Characterize Organic Matter-Iron Phases Relevant to Passive Mine Waste Remediation Systems. Supervisor: McBeth, Joyce. Saskatchewan, Canada: University of Saskatchewan. https://hdl.handle.net/10388/14832. |
BIOXAS-IMAGING, BIOXAS-MAIN, BXDS-WHE, CMCF-BM, SGM, SXRMB |
Masters Thesis |
Environment |
Uwanyirigira, Janviere (2023). Integrated Synchrotron Approaches to Characterize Organic Matter-Iron Phases Relevant to Passive Mine Waste Remediation Systems. Supervisor: McBeth, Joyce. Saskatchewan, Canada: University of Saskatchewan. https://hdl.handle.net/10388/14832. |
BIOXAS-IMAGING, BIOXAS-MAIN, BXDS-WHE, CMCF-BM, SGM, SXRMB |
Masters Thesis |
Environment |
Uwanyirigira, Janviere (2023). Integrated Synchrotron Approaches to Characterize Organic Matter-Iron Phases Relevant to Passive Mine Waste Remediation Systems. Supervisor: McBeth, Joyce. Saskatchewan, Canada: University of Saskatchewan. https://hdl.handle.net/10388/14832. |
BIOXAS-IMAGING, BIOXAS-MAIN, BXDS-WHE, CMCF-BM, SGM, SXRMB |
Masters Thesis |
Environment |
Uwanyirigira, Janviere (2023). Integrated Synchrotron Approaches to Characterize Organic Matter-Iron Phases Relevant to Passive Mine Waste Remediation Systems. Supervisor: McBeth, Joyce. Saskatchewan, Canada: University of Saskatchewan. https://hdl.handle.net/10388/14832. |
BIOXAS-IMAGING, BIOXAS-MAIN, BXDS-WHE, CMCF-BM, SGM, SXRMB |
Masters Thesis |
Environment |
Uwanyirigira, Janviere (2023). Integrated Synchrotron Approaches to Characterize Organic Matter-Iron Phases Relevant to Passive Mine Waste Remediation Systems. Supervisor: McBeth, Joyce. Saskatchewan, Canada: University of Saskatchewan. https://hdl.handle.net/10388/14832. |
BIOXAS-IMAGING, BIOXAS-MAIN, BXDS-WHE, CMCF-BM, SGM, SXRMB |
Masters Thesis |
Environment |
Xu, Jiabin; Feng, Kun; Lu, Cheng; Wang, Xuchun; Chen, Jiatang et al. (2023). Atomically Dispersed Mg–N–C Material Supported Highly Crystalline Pt3Mg Nanoalloys for Efficient Oxygen Reduction Reaction. Journal of Physical Chemistry Letters 14(37) , 8296-8305. 10.1021/acs.jpclett.3c01870. |
CLS-APS, HXMA, SGM, SXRMB |
Peer-Reviewed Article |
Materials |
Xu, Jiabin; Feng, Kun; Lu, Cheng; Wang, Xuchun; Chen, Jiatang et al. (2023). Atomically Dispersed Mg–N–C Material Supported Highly Crystalline Pt3Mg Nanoalloys for Efficient Oxygen Reduction Reaction. Journal of Physical Chemistry Letters 14(37) , 8296-8305. 10.1021/acs.jpclett.3c01870. |
CLS-APS, HXMA, SGM, SXRMB |
Peer-Reviewed Article |
Materials |
Xu, Jiabin; Feng, Kun; Lu, Cheng; Wang, Xuchun; Chen, Jiatang et al. (2023). Atomically Dispersed Mg–N–C Material Supported Highly Crystalline Pt3Mg Nanoalloys for Efficient Oxygen Reduction Reaction. Journal of Physical Chemistry Letters 14(37) , 8296-8305. 10.1021/acs.jpclett.3c01870. |
CLS-APS, HXMA, SGM, SXRMB |
Peer-Reviewed Article |
Materials |