Publication Beamlines Strategic Pillar
Lardner; Michael J (2016). Spatiotemporal Mapping of Electrochemical Diffusion Layers. Supervisor: Burgess, Ian. Saskatchewan, Canada: University of Saskatchewan. Lardner, Michael J. MID-IR Materials
Michael Pravica (2021). Polymer compositions. Patent Number: US10907014B2. FAR-IR, MID-IR, SYLMAND Materials
Ketki Srivastava (2024). Everything, Everywhere, All At Once: Micro- and Nano-Fabrication for Sensitive, Homogenous and Spatio-Temporally-Resolved Raman and Infrared Spectroscopy Sensors. Supervisor: Odijk, M.; van den Berg, A.. Enschede, The Netherlands: University of Twente. https://doi.org/10.3990/1.9789036562171. MID-IR, SYLMAND Materials
Danielle McRae (2020). Plasmon-Enabled Physical and Chemical Transformations of Nanomaterials. Supervisor: Francois Lagugne-Labarthet. Ontario, Canada: University of Western Ontario. https://ir.lib.uwo.ca/etd/7068/. MID-IR Materials
Erick Soares Lins (2022). Dual Optical Frequency Comb Time-resolved Spectroscopy for Surface-Enhanced Spectroelectrochemistry. Supervisor: Burgess, Ian, J.. Saskatchewan, Canada: University of Saskatchewan. https://harvest.usask.ca/items/f9cae4bf-cc01-4c67-b75d-0e5631d7cc1c. MID-IR Materials
Denis AB Therien (2022). Plasmonically-Active Nanomaterials for Enhanced Second- Harmonic Generation and Chemical ReactionsHarmonic Generation and Chemical Reaction. Supervisor: Lagugné-Labarthet, François. Ontario, Canada: The University of Western Ontario. https://ir.lib.uwo.ca/etd/8536. MID-IR Materials
Tyler A. Morhart (2021). Surface-Enhanced Spectroelectrochemistry using Synchrotron Infrared Radiation. Supervisor: Burgess, Ian J.. Saskatchewan, Canada: University of Saskatchewan. https://harvest.usask.ca/handle/10388/13617. MID-IR, SYLMAND Materials
Tu; Kaiyang (2020). Developing Time-Resolved Synchrotron Infrared Spectroscopy for Spectroelectrochemical Measurements. Supervisor: Burgess, Ian J. Saskatchewan, Canada: University of Saskatchewan. https://harvest.usask.ca/handle/10388/12754. MID-IR, SYLMAND Materials
Rema; Tara (2016). Microscopic and molecular assessment of chlorhexidine tolerance mechanisms in Delftia acidovorans biofilms. Supervisor: Korber, Darren; Lawrence, John. Saskatchewan, Canada: University of Saskatchewan. https://ecommons.usask.ca/handle/10388/ETD-2016-03-2469. MID-IR, SM Materials
Alivia Mukherjee (2022). Generation of activated carbon from spent coffee grounds: Process optimization, kinetics and CO2 capture. Supervisor: Ajay K. Dalai, Catherine Niu. Saskatchewan, Canada: University of Saskatchewan. https://hdl.handle.net/10388/14190. MID-IR, SGM Materials
Srivastava, K.; Boyle, N. D.; Jorissen, K.F.A; Burgess, I. J.; Van Der Stam, W. et al. (2022). ATR microreactor: A tool for in-situ and spatial reaction monitoring. . 10.1109/sensors52175.2022.9967095. MID-IR Materials
Mikhchian, Mehrnaz; Grosvenor, Andrew P. (2025). A comparative study of the long-term aqueous durability of brannerite (Ce0.94Ti2O6–δ) and glass-brannerite (Fe-Al-BG-Ce0.94Ti2O6–δ) composite materials. Applied Surface Science 687, 162233. 10.1016/j.apsusc.2024.162233. IDEAS, SXRMB, VLS-PGM Materials
Shi, Qinhao; Qi, Ruijuan; Feng, Xiaochen; Wang, Jing; Li, Yong et al. (2022). Niobium-doped layered cathode material for high-power and low-temperature sodium-ion batteries. Nature Communications 13(1) , 3205. 10.1038/s41467-022-30942-z. IDEAS, SXRMB Materials
Geng, Chenxi; Rathore, Divya; Heino, Dylan; Zhang, Ning; Hamam, Ines et al. (2021). Mechanism of Action of the Tungsten Dopant in LiNiO 2 Positive Electrode Materials. Advanced Energy Materials 12(6) , 2103067. 10.1002/aenm.202103067. IDEAS Materials
O'Sullivan, Eugene J.; Camagong, C; Lavoie, C.; Jordan-Sweet, J.; Muir, D. et al. (2020). Electroless Deposition for Nanoscale Applications: Challenges and Opportunities. ECS Meeting Abstracts MA2020-02(17) , 1487-1487. 10.1149/ma2020-02171487mtgabs. IDEAS Materials