Two SALA projects awarded SSHRC funds
Two SALA projects awarded SSHRC funds matthew.wattier Fri, 09/13/2024 - 14:35 SALA External This article originally appeared on UBC Research + Innovation. Strategic Priority Areas...
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The applied sciences – architecture, landscape architecture, engineering, nursing, and planning – change society's conception of what is possible as a matter of course. Applied scientists make dreams real, turn ideas into practice. We embody the interface between present and future.
The Faculty of Applied Science comprises a unique constellation of professional disciplines including; Architecture & Landscape Architecture, Engineering, Nursing and Community & Regional Planning. The core purpose shared across all of our four disciplines is to discover, create and apply knowledge, provide unwavering top-tier education and champion a community of responsible professionals devoted to serving a thriving, sustainable and healthy society. Our work and the professions which our graduates represent span the entire human-centred built environment.
The disciplines within the Faculty of Applied Science are celebrated for the scope, strength and impact of their research activities. Our Faculty claims the spotlight in the global arena for our research in clean energy, communication and digital technologies, health and health technology among many others. We offer disciplinary-specific research based graduate programs as well as a range of professional graduate programs and pride ourselves on our ability to open doors of opportunity to students beyond their time within our Faculty.
Research Centres
Schools / Departments
Graduate Degree Programs
Recent Publications
This is an incomplete sample of recent publications in chronological order by UBC faculty members with a primary appointment in the Faculty of Applied Science.
Recent Thesis Submissions
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Design recipe automation for silicon photonics (EECE - MASC)
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Energy distribution of thermal electron emission (EECE - PHD)
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Towards a unified electro-optic circuits co-simulation (EECE - MASC)
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Low-cost scanning electron microscope (EECE - MASC)
Doctoral Citations
A doctoral citation summarizes the nature of the independent research, provides a high-level overview of the study, states the significance of the work and says who will benefit from the findings in clear, non-specialized language, so that members of a lay audience will understand it.
| Year | Citation | Program |
|---|---|---|
| 2020 | Dr. Gubran studied the hardware architecture of low-power integrated computer chips of mobile devices. He created modeling tools and developed hardware techniques that can aid researchers and chip architects in understanding, designing, and improving the performance and power-efficiency of mobile chips. | Doctor of Philosophy in Electrical and Computer Engineering (PhD) |
| 2020 | Dr. Serrano-Mora studied the use of activated carbon electrodes to desalinate brackish water. He analyzed the long-term influence of commonly found water components and different approaches to restore their desalination capacity. This research advances the development of Capacitive Deionization for the production of freshwater using saline sources. | Doctor of Philosophy in Chemical and Biological Engineering (PhD) |
| 2020 | Dr. Haq's research focused on detecting groups within a biomedical system. She proposed novel methods to find groups in two crucial brain structures, brainstem and putamen, which play important roles in understanding several neurological diseases. She also investigated groups of similar X-ray images to generate a guidance tool for diagnosis. | Doctor of Philosophy in Electrical and Computer Engineering (PhD) |
| 2020 | Dr. Gavrilovic examined the lifecycle performance of buildings that have been damaged during earthquakes. Simulating the repair of damage on a computer, new results provide insights into the costs, repairability, and sustainability of several structural materials. This research will assist in the design of more resilient and sustainable buildings. | Doctor of Philosophy in Civil Engineering (PhD) |
| 2020 | Dr. Dong studied the methods to apply renewable energy and artificial intelligence to wireless communication systems. He found that there exists a tradeoff between users' quality of experience and system energy expenditure. His developed algorithms will help to reduce the carbon-dioxide equivalent emissions of wireless communications. | Doctor of Philosophy in Electrical and Computer Engineering (PhD) |
| 2020 | By studying the integrity of titanium exposed to mineral slurries in hydrometallurgy, Dr. Liu found that mineral solids can result in the wear and corrosion of titanium. Her research related titanium's corrosion resistance to prevailing environmental conditions. Her work will improve the safety and economics of processing plants that use titanium. | Doctor of Philosophy in Materials Engineering (PhD) |
| 2020 | Dr. Kim studied particle breakage in sorption-enhanced chemical looping, which produces H2-enriched synthesis gas while capturing CO2 from fuels. He examined the breakage of oxygen carrier and CO2 sorbent particles and developed a model to improve the efficiency and stability of the process to reduce the impact on public health and the environment. | Doctor of Philosophy in Chemical and Biological Engineering (PhD) |
| 2020 | Dr. Mustard investigated how to improve the speed of data analysis on computer systems. He developed a system that runs analysis tasks on novel computer processors that efficiently communicate over data center networks. His research provides insights into how and when to use these new designs to make data analysis faster for everyday users. | Doctor of Philosophy in Electrical and Computer Engineering (PhD) |
| 2020 | Dr. Ebneyamini's research focused on the regeneration of limestone-based particles as sorbents for the capture of CO2 via calcium-looping. His work introduced a novel technology, capable of efficient sorbent regeneration at relatively mild temperatures. The process also benefits from CO2 utilization, reducing greenhouse gas emissions. | Doctor of Philosophy in Chemical and Biological Engineering (PhD) |
| 2020 | Dr. Mitra examined the effect of separate refining and co-refining of mixtures of softwood and hardwood pulps in terms of paper tensile strength. He developed a scaling law for tensile strength increase during refining of pulp mixtures, which will help use NBSK pulp to the highest potential and achieve target strengths depending on grades of paper. | Doctor of Philosophy in Chemical and Biological Engineering (PhD) |