Adhesion and Surface Layers on Silicon Anodes Suppress Formation of c-Li3.75Si and Solid Electrolyte InterphasePublication with our German collaborators on nanostructuring of high energy capacity batteries. | Publication | 2020-02-18 | Sayed Youssef Sayed Nagy, "Hezhen Xie", Jillian Mary Buriak, "Peter Kalsivart", Erik Luber, Brian Olsen, "Peter Müller-Buschbaum" |
Alternating Silicon and Carbon Multilayer-Structured Anodes Suppress Formation of the c‑Li3.75Si Phase | Publication | 2019-05-23 | Jillian Mary Buriak, Erik Luber, Brian Olsen, "Peter Kalisvaart", "Hezhen Xie", Sayed Youssef Sayed Nagy |
Beyond Thin Films: Clarifying the Impact of c-Li15Si4 Formation in Thin Film, Nanoparticle, and Porous Si ElectrodesPublication of original research | Publication | 2021-08-06 | Jasper Woodard, "peter kalisvaart", Sayed Youssef Sayed Nagy, Brian Olsen, Jillian Mary Buriak |
Bipolar Resistive Switching in Junctions of Gallium Oxide and p-type Silicon | Publication | 2021-03-29 | Mahmoud N Almadhoun, "Maximilian Speckbacher", Brian Olsen, Erik Luber, Sayed Youssef Sayed Nagy, "Marc Tornow", Jillian Mary Buriak |
Mixing, Domains, and Fast Li-Ion Dynamics in Ternary Li–Sb–Bi Battery Anode AlloysPublication of original research | Publication | 2022-02-01 | Vladimir K Michaelis, Jillian Mary Buriak, Madhu Sudan Chaudhary, Amit Bhattacharya, "Peter Kalisvaart" |
Optimization of the Bulk Heterojunction of All–Small-Molecule Organic Photovoltaics Using Design of Experiment and Machine Learning Approaches. | Publication | 2020-11-23 | Aaron Kirkey, Erik Luber, Bing Cao, Brian Olsen, Jillian Mary Buriak |
Redox Flow Batteries: How to Determine Electrochemical Kinetic ParametersPublication in one of the top journals in nanoscience. Describes how to properly analyze redox flow batteries. | Publication | 2020-03-17 | Sayed Youssef Sayed Nagy, Jillian Mary Buriak, Hao Wang, Erik Luber, Brian Olsen, "Richard McCreery", "Eugene Smotkin" |
Solvent Vapor Annealing, Defect Analysis, and Optimization of Self-Assembly of Block Copolymers Using Machine Learning ApproachesPublication of original research | Publication | 2021-06-08 | "Gayashani Ginige", "Youngdong Song", Brian Olsen, Erik Luber, Cafer T Yavuz, Jillian Mary Buriak |
Stabilizing Tin Anodes in Sodium-Ion Batteries by Alloying with Silicon | Publication | 2020-09-23 | Sayed Youssef Sayed Nagy, W Peter Kalisvaart, Brian Olsen, Erik Luber, Jillian Mary Buriak |
Tailoring Morphology Compatibility and Device Stability by Adding PBDTTPD-COOH as Third Component to Fullerene-Based Polymer Solar Cells | Publication | 2020-02-18 | "Dan Yang", Bing Cao, "Volker Körstgens", "Nitin Saxena", "Nian Li", "Christoph Bilko", "Sebastian Grott", "Wei Chen", "Xinyu Jiang", Julian Eliah Heger, "Sigrid Bernstorff", "Peter Müller-Buschbaum" |
UV-Initiated Si–S, Si–Se and Si–Te Bond Formation on Si(111): Coverage, Mechanism, and Electronics | Publication | 2018-03-01 | Minjia Hu |
Water-soluble pH-switchable cobalt complexes for aqueous symmetric redox flow batteriesResearch that was featured on the cover of the journal. Work outlines a new redox flow battery system.
| Publication | 2020-03-10 | Jillian Mary Buriak, Erik Luber, Brian Olsen, Hao Wang, Sayed Youssef Sayed Nagy |
Chemistry of Materials Lectureship and Best Paper Award | Award | 2019-08-25 | Jillian Mary Buriak |
Covestro Distinguished Lecture Endowed Lectureship at the University of Pittsburgh. | Award | 2019-04-18 | Jillian Mary Buriak |
Covestro Lectureship of Energy | Award | 2018-05-15 | Jillian Mary Buriak |
D. B. Robinson Lecture | Award | 2019-09-05 | Jillian Mary Buriak |
Graduate ScholarshipAITF Master's scholarship:
Understanding the Interactions of Photoactive Components in Small Molecule Organic Photovoltaics Through
Design of Experiments and Machine Learning | Award | 2019-01-07 | Aaron Kirkey |
GreenSTEM Entrepreneurial FellowshipGreenSTEM is an entrepreneurial pilot program funded by the Government of Alberta for Science, Technology, Engineering, and Math (STEM) Masters and Ph.D. graduates. The pilot program enables entrepreneurship and provides a two-year commercialization runway for “deep technology” companies. Upon receiving the fellowship, Dr. Bing Cao co-founded Nanode Battery Technologies Ltd. to commercialize the free-standing and high-performance anodes for lithium and sodium-ion batteries. The Nanode product reduces the anode volume by 75% and increases the energy density by 50%. | Award | 2020-07-01 | Bing Cao |
Hach LectureshipAnnual lectureship at Colorado State University | Award | 2019-04-18 | Jillian Mary Buriak |
Ivy A Thomson and William A Thomson Graduate Scholarship2018 Ivy A Thomson and William A Thomson Graduate Scholarship of the University of Alberta | Award | 2018-07-11 | Minjia Hu |
Lectureship Laureate North American winner of the ACS Nano Lectureship: https://pubs.acs.org/doi/10.1021/acsnano.0c01221 | Award | 2020-05-29 | Jillian Mary Buriak |
McRae Annual Lectureship | Award | 2019-12-01 | Jillian Mary Buriak |
MITACS Global Link AwardMITACS award to fund Aaron Kirkey to spend 3 months at the Technical University of Munich, Germany, working on understanding the nanostructure of organic photovoltaics. | Award | 2019-01-23 | Aaron Kirkey |
Québec Centre for Advanced Materials (CQMF) Annual Lectureship | Award | 2019-12-09 | Jillian Mary Buriak |
Rio Tinto Alcan AwardTop award for inorganic chemistry/Canadian Society for Chemistry.
http://cscid.chem.ubc.ca/content/buriak-wins-rio-tinto-alcan-award | Award | 2019-04-18 | Jillian Mary Buriak |
SciFinder Future Leaders | Award | 2017-08-09 | Minjia Hu |
Travel Award | Award | 2019-08-14 | Minjia Hu |
Undergraduate Student Research Award (USRA)Phillip Kirwin performed an in-depth study of halide perovskite semiconductor active layers and halide perovskite solar cells using coupled optical+electronic material and device modeling. | Award | 2017-05-01 | Phillip Suwan Kirwin |
XingDa Lectureship | Award | 2018-04-20 | Jillian Mary Buriak |
30th Anniversary of Chemistry of Materials - from 1989 to 2019 | Activity | 2019-04-01 | Jillian Mary Buriak |
ABBY-Net Summer School: Natural Resource Management and Energy Systems Under Changing Environmental ConditionsInvited to attend the ABBY-Net Summer School in Munich, Germany: Natural Resource Management and Energy Systems Under Changing Environmental Conditions, focusing on energy-management issues in the free-state of Bavaria, and the impact of the “Energiewende” on natural ecosystem functioning | Activity | 2018-08-11 | Minjia Hu |
Alloyed Anodes for Sodium Ion Batteries | Activity | 2019-11-17 | Jillian Mary Buriak |
Application of Machine Learning and Design of Experiments (DoE) to Device Optimization: Organic PhotovoltaicsKeynote talk by Buriak. "Application of Machine Learning and Design of Experiments (DoE) to Device Optimization: Organic Photovoltaics"
KAIST International MSE Workshop 2018
https://mse.kaist.ac.kr
https://axial.acs.org/2018/08/15/kaist-2018/ | Activity | 2019-04-18 | Jillian Mary Buriak |
Coverage, Mechanism, and Electronics Study of Si–S, Si–Se and Si–Te-bound Si(111) Surfaces Formed via UV Irradiation101st Canadian Chemistry Conference and Exhibition, Edmonton, Canada, May 27–31, 2018. | Activity | 2018-05-27 | Minjia Hu, Tate Hauger, Brian Olsen, Erik Luber, Jillian Mary Buriak |
Coverage, Mechanism, and Electronics Study of Si–S, Si–Se and Si–Te-bound Si(111) Surfaces Formed via UV Irradiation | Activity | 2018-05-27 | Minjia Hu |
Design of Experiments & Machine Learning Applied to Organic Photovoltaics | Activity | 2019-06-03 | Jillian Mary Buriak |
Design of Experiments and Machine Learning-Assisted Organic Solar Cell Efficiency OptimizationOrganic solar cells (OSCs) represent a cost-effective way to transform solar energy into electricity due to their potential for low-cost and high-throughput roll-to-roll production.[1] Improving OSC efficiency and stability are two of the most important tasks on the way toward commercialization. While much effort has been focused on developing new materials, there is enormous room with respect to optimization of the processing of OSCs to achieve optimal performance of a particular photoactive material. Morphology of the bulk heterojunction, the most important layer within an OSC, results from nanoscale phase segregation that depends extensively upon processing. However, the optimization process for an OSC is tedious, time-consuming and expensive involving many parameters. Conventional optimization uses unimodal approach where one parameter is optimized while all others are kept constant. This can take months or years. Moreover, there is an associated risk of missing the optimal results because all experimental combinations for all parameters cannot be performed. Herein, we report an approach that uses Design of Experiments (DOE) along with machine learning statistical data analysis to effectively and efficiently optimize solar cell efficiency. Machine learning algorithms are trained to find patterns in datasets which could greatly assist data analysis and parameter importance evaluation, hence predict the results for future experiments.[2] DOE methods allow experimentalists to explore a larger parameter space with fewer experimental trials while obtaining valid and objective conclusions. We show that, using the principles of DOE to plan experiments combined with using machine learning assist in the prediction of optimized solar cells. Specific examples of concrete improvement of the power conversion efficiency of OSCs will be described. University of Alberta | Activity | 2018-05-25 | Bing Cao, Adutwum, L., Brian Olsen, Oliynyk, A., Erik Luber, Tate Hauger, Mar, A., Jillian Mary Buriak |
Effectively Exploring Parameter Space: Design of Experiments and Machine Learning-assisted Organic Solar Cell Efficiency OptimizationInvited talk at the annual American Physical Society meeting, Boston, MA
https://meetings.aps.org/Meeting/MAR19/Session/B55.7 University of Alberta | Activity | 2019-03-04 | Erik Luber, Brian Olsen, Mar, A., Oliynyk, A., Adutwum, L., Jillian Mary Buriak |
Functionalized Silicon Anodes for Lithium Ion BatteriesA Poster Presented at the 2019 FES Colloquium on efforts to modify silicon through hydrosilylation and electrochemistry in order to improve cycling in lithium ion batteries. | Activity | 2019-05-07 | Jasper Woodard, "Peter Kalisvaart", Sayed Youssef Sayed Nagy, Jillian Mary Buriak |
Future Science 2019 | Activity | 2019-10-07 | Jillian Mary Buriak |
Invited seminar, Northwestern University, Evanston ILInvited seminar (Frontiers in Nanotechnology Seminar) | Activity | 2018-11-20 | Jillian Mary Buriak |
Invited seminar, University of Washington, Chemical Engineering Invited seminar, University of Washington, Chemical Engineering | Activity | 2018-11-05 | Jillian Mary Buriak |
Invited talk: ACS national meeting, Boston Invited seminar at NASA symposium on space exploration. Seminar was about solar energy optimization. Talk by Buriak. University of Alberta | Activity | 2019-04-18 | Jillian Mary Buriak, Mar, A., Oliynyk, A., Adutwum, L., Erik Luber, Brian Olsen |
Invited talk: CSC meeting Invited talk, "Reconsideration of OPV: Addressing Key Bottlenecks with Simple Predictive Models and Machine Learning Approaches"
Canadian Society for Chemistry meeting | Activity | 2018-05-27 | Jillian Mary Buriak |
Nanomaterials for Energy and Life Sciences | Activity | 2019-09-29 | Jillian Mary Buriak |
Plenary talk, Southeast regional ACS meeting, Georgia, USAPatterning with polymers and plasmons (and people!)
| Activity | 2018-11-22 | Jillian Mary Buriak |
Silicon Thin Films: Buffer Elements for Better PerformanceContributed talk, 101st Canadian Society for Chemistry Conference, Edmonton, May 2018 | Activity | 2018-05-27 | Sayed Youssef Sayed Nagy, Jillian Mary Buriak |
Silicon Thin Films: Buffer Elements for Better Performance | Activity | 2018-05-30 | Sayed Youssef Sayed Nagy, " Peter Peter Peter Peter Kalisvaart, Jillian Mary Buriak |
Water-Soluble pH-Switchable Cobalt Complexes for Aqueous Symmetric Redox Flow BatteriesPoster | Activity | 2019-11-19 | Hao Wang, Sayed Youssef Sayed Nagy, "Yuqiao Zhou", Brian Olsen, Erik Luber, Jillian Mary Buriak |
Water-Soluble pH-Switchable Cobalt Complexes for Aqueous Symmetric Redox Flow Batteries | Activity | 2020-03-03 | Hao Wang, Sayed Youssef Sayed Nagy, "Yuqiao Zhou", Brian Olsen, Erik Luber, Jillian Mary Buriak |
Molecular Engineering and Electrochemical Characterization of Redox-active Electrolytes for Aqueous Redox Flow Batteries Ph.D. Thesis | Publication | 2021-05-17 | Hao Wang |
Machine-Learning and Design of Experiments-based Optimization of Organic Solar CellsOver the coming decades, global population and energy consumption are projected to increase dramatically, with the latter doubling by 2050 as per the most conservative estimates. Much of this demand is likely to be met with increased use of fossil fuels. The burning of fossil fuels is a major contributor to the ever-increasing CO 2 concentration in the atmosphere, a major driver of climate change. In order for countries and companies to meet their climate targets, they must undergo a transition to low or CO 2 -free energy sources (wind, solar, hydroelectric, for example). Solar power, typically harvested using photovoltaic and solar thermal devices, is considered one of the most promising renewable energy technologies due to the sheer quantity of solar irradiation impinging upon terrestrial earth. Organic photovoltaics (OPVs) are a subset of PV technology that are thin, lightweight, printable using roll-to-roll and spray coating technologies, flexible, and can be made semi-transparent. These features enable this class of photovoltaics to be considered in markets and locales otherwise inaccessible to traditional silicon devices, which are heavy and cumbersome. Organic photovoltaics comprise many layers that need to be manufactured with great care in order to yield devices capable of producing substantial power, in a reproducible fashion. The central layer in this stack is the critical light absorbing layer that consists of two or three, and occasionally more, different organic molecules. | Publication | 2020-08-31 | Aaron Kirkey |
ABBY-Net Summer Schoolfocusing on energy-management issues in the free-state of Bavaria, and the impact of the “Energiewende” on natural ecosystem functioning
seminars on key topics including hydrology, energy systems, environmental monitoring, data mining, and data analysis
field excursions designed to educate participants on local energy-management issues
develop inter-disciplinary research proposals designed to solve practical problems related to energy-management in Bavaria. | Activity | 2018-08-11 | Minjia Hu |
Connecting the Chemistry of Silanes and Silicon Surfaces with Radical-based Mechanisms9th European Silicon Days. Connecting the Chemistry of Silanes and Silicon Surfaces with Radical-based Mechanisms | Activity | 2018-09-09 | Jillian Mary Buriak |
Invited seminar, University of PittsburghConnecting Molecules & Surfaces: Mechanisms, Materials (technical talk that accompanied the Covestro Lecture). | Activity | 2018-10-04 | Jillian Mary Buriak |
Invited seminar: Materials, Molecules, & Mechanisms: The Chemistry of Silicon Surfaces and Silanes Invited seminar, McMaster University, Chemical and Materials Engineering | Activity | 2018-12-10 | Jillian Mary Buriak |
Challenges and Opportunities in Designing Perovskite Nanocrystal Heterostructures | Publication | 2020-06-01 | Prashant V Kamat, Narayan Pradhan, Kirk Schanze, Paul S Weiss, Jillian Mary Buriak, Peter Stang, Teri W Odom, Gregory Hartland |
How To Optimize Materials and Devices via Design of Experiments and Machine Learning: Demonstration Using Organic PhotovoltaicsThis widely publicized paper, in the form of a “Perspective,” was the result of an ongoing collaboration between the Buriak and Mar group, illustrating how machine learning is applied to optimize several experimental conditions so that efficiencies of photovoltaic devices can be rapidly improved. [To date, this paper has been viewed over 7100 times in just over a year.] University of Alberta | Publication | 2018-07-01 | Bing Cao, Lawrence A Adutwum, Anton O Oliynyk, Erik J Luber, Brian C Olsen, Mar, A., Jillian Mary Buriak |
In-Operando Study of the Effects of Solvent Additives on the Stability of Organic Solar Cells Based on PTB 7-Th:PC71BM | Publication | 2019-01-01 | Dan Yang, Franziska C Löhrer, Volker Körstgens, Armin Schreiber, Sigrid Bernstorff, Jillian Mary Buriak, Peter Müller-Buschbaum |
Mechanochemical Synthesis of Methylammonium Lead Mixed\textendash Halide Perovskites: Unraveling the Solid-Solution Behavior Using Solid-State NMRMixed-halide lead perovskite (MHP) materials are rapidly advancing as next-generation high-efficiency perovskite solar cells due to enhanced stability and bandgap tunability. In this work, we demonstrate the ability to readily and stoichiometrically tune the halide composition in methylammonium-based MHPs using a mechanochemical synthesis approach. Using this solvent-free protocol we are able to prepare domain-free MHP solid solutions with randomly distributed halide ions about the Pb center. Up to seven distinct [PbClxBr6–x]4– environments are identified, based on the 207Pb NMR chemical shifts, which are also sensitive to the changes in the unit cell dimensions resulting from the substitution of Br by Cl, obeying Vegard’s law. We demonstrate a straightforward and rapid synthetic approach to forming highly tunable stoichiometric MHP solid solutions while avoiding the traditional solution synthesis method by redirecting the thermodynamically driven compositions. Moreover, we illustrate the importance of complementary characterization methods, obtaining atomic-scale structural information from multinuclear, multifield, and multidimensional solid-state magnetic resonance spectroscopy, as well as from quantum chemical calculations and long-range structural details using powder X-ray diffraction. The solvent-free mechanochemical synthesis approach is also compared to traditional solvent synthesis, revealing identical solid-solution behavior; however, the mechanochemical approach offers superior control over the stoichiometry of the final mixed-halide composition, which is essential for device engineering. University of Alberta | Publication | 2018-03-01 | Abhoy Karmakar, Abdelrahman M Askar, Guy M Bernard, Victor V Terskikh, Michelle Ha, Sahil Patel, Shankar, K., Vladimir K Michaelis |
Melanin-based electronics: From proton conductors to photovoltaics and beyond University of Alberta | Publication | 2018-09-07 | Ehsan Vahidzadeh, "Aarat Kalra", Shankar, K. |
Phase Evolution in Methylammonium Tin Halide Perovskites with Variable Temperature Solid-State 119Sn NMR Spectroscopy University of Alberta | Publication | 2020-07-01 | Michelle Ha, Abhoy Karmakar, Guy Bernard, Enoc Basilio, Arun Krishnamurthy, Abdelrahman M Askar, Shankar, K., Scott Kroeker, Vladimir K Michaelis |
Plexcitonics – Fundamental principles and optoelectronic applicationsThe nanoscale confinement and coupling of electromagnetic radiation into plexcitonic modes has drawn immense interest because of the innovative possibilities for their application in light harvesting and light emitting devices (LEDs). Plexcitons arise from the coupling between two types of quasiparticles, plasmons and excitons, and can be distinguished by the strength of the coupling into strong and weak coupling regimes. Plexcitons have been used to modulate the rate of Förster-type resonance energy transfer in quantum dot assemblies and enhance the spontaneous emission rate in quantum dot LEDs. The clearest examples of a plexcitonic enhancement of photocatalytic reaction rates have been evidenced in hybrid systems wherein the strongly bound exciton found in 2D sheet-like semiconductors is coupled to the surface plasmon resonance of close-lying noble metal nanoparticles. Plexcitonic photocatalysts and solar cells aim to increase the lifetime of hot carriers and thereby enhance the quantum yields for energy harvesting. Since plexcitonics requires the placement of plasmonic and excitonic components in close proximity with one another to facilitate their coupling, it provides a rich arena for chemists and materials scientists to form deterministic and non-deterministic arrays and heterojunctions involving noble metal thin films and nanostructures, quantum dots and dye molecules. This review summarizes the dynamics of plexcitons in the various composite systems and provides an overview of the latest theoretical and experimental developments in the field of plexcitonics. University of Alberta | Publication | 2019-01-02 | Ajay Manuel, Aaron Kirkey, Najia Mahdi, Shankar, K. |
Preferentially Oriented TiO2 Nanotube Arrays on Non-Native Substrates and Their Improved Performance as Electron Transporting Layer in Halide Perovskite Solar Cells University of Alberta | Publication | 2019-10-19 | Ryan Kisslinger, "Abdelrahman Askar", Ujwal Thakur, Saralyn Riddell, Darren Dahunsi, Yun Zhang, Sheng Zeng, Ankur Goswami, Shankar, K. |
Reconsidering X-ray Photoelectron Spectroscopy Quantification of Substitution Levels of Monolayers on Unoxidized Silicon Surfaces | Publication | 2020-06-01 | Minjia Hu, Erik J Luber, Jillian Mary Buriak |
Sb\textendash Si Alloys and Multilayers for Sodium-Ion Battery Anodes | Publication | 2019-02-01 | W Peter Kalisvaart, Brian C Olsen, Erik J Luber, Jillian Mary Buriak |
Triplet excitons: improving exciton diffusion length for enhanced organic photovoltaics University of Alberta | Publication | 2019-01-05 | Bruno Luppi, "Darren Majak", Manisha Gupta, Eric Rivard, Shankar, K. |
Unusual Surface Ligand Doping-Induced p-Type Quantum Dot Solids and Their Application in Solar CellsDoping quantum dots (QDs) is a problem that has been haunting researchers in the QD research community for years, even though doping techniques have been utilized for decades in conventional semiconductors. For the “self-purification” in colloidal QDs, engineering the surface ligands has emerged as an effective way to alter free carrier concentrations and doping types in colloidal QD solids. Halide-atomic ligands are the most popular ligands in producing PbS QD solids since they provide minimal dot-to-dot distance while maintain low in-gap trap states. However, previously reported halide surface treatment could only produce n-type QD solids. Here, we report the fabrication of p-type PbS QD solids using proton-assisted surface ligand exchange. We unveiled the origin of p-type doing in PbS QD solids, and it came from an unusual surface ligand; the HOH+ group formed using NH4X (X = Cl, Br, I) in methanol. We further fabricated QD solar cells using PbS–NH4Cl, a p-type QD solid predicted and proved by our theory and experiments. The champion device shows a high power conversion efficiency of 7.49%. University of Alberta | Publication | 2020-11-01 | Lingju Meng, Qiwei Xu, Ujwal Thakur, Lu Gong, Zeng, H., Shankar, K., Xihua Wang |
van der Waals Epitaxy of Soft Twisted Bilayers: Lattice Relaxation and Mass Density Waves | Publication | 2020-09-01 | Cong Jin, Brian C Olsen, Erik J Luber, Jillian Mary Buriak |
3-month research stay3-month research stay in the laboratory of Prof. P. Mueller-Buschbaum, TUM, Munich, Germany
https://www.groups.ph.tum.de/en/polymer/peter-mueller-buschbaum/ | Activity | 2019-01-17 | Aaron Kirkey |