Engineering for a Sustainable Future
Research subthemes
- Infrastructure: sustainable, reliable, and resilient infrastructure addressing climate, environmental, social, and economic challenges
- Sustainable construction: environmentally responsible materials, energy-efficient techniques, and innovative technologies to minimize ecological impact
- Resilient design: nature-based solutions to withstand disasters, climate change, and disruptions
- Sustainable transportation: active mobility, electrification, alternative fuels, and disruptive technologies
- Technological integration: IoT, big data, and predictive analytics for improved mobility, efficiency, and urban network resilience
- Urban planning priorities: emission reductions, improved accessibility, and integration of bike lanes, sidewalks, and pedestrian-friendly spaces
- Environmental restoration: soil and waste management for land restoration
- Air pollution mitigation: emission reduction, carbon capture, and advanced monitoring
- Sustainable infrastructure: nature-based solutions for pollution control and restoration
- Technological advancements: hydrological modelling, remote sensing, and predictive analytics improve water availability assessments and infrastructure vulnerability analysis
- Integrated water management: open-source modelling tools, AI/ML applications, and real-time monitoring enable informed decision-making
- Efficient water treatment: Advanced technologies enhance pollutant fate and transport understanding, improving industrial and municipal wastewater management
- Technological advancements: sensor technology and predictive modelling are used for environmental assessments and risk management
- Disaster preparedness: climate change adaptation strategies are employed for proactive disaster planning
- Environmental monitoring: environmental changes and climate impacts are assessed through monitoring
Results for:
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Schulich School of Engineering, Sustainable Systems Engineering -
Schulich School of Engineering, Sustainable Systems Engineering -
Schulich School of Engineering, Department of Chemical and Petroleum EngineeringBiological carbon capture and conversion; Biomaterials; Microalgal Biotechnology; Oleochemicals -
Schulich School of Engineering, Department of Electrical and Software EngineeringMemory Empowerment, Sustainable Software Engineering, Requirements Engineering , Transient Micro-services, Green DevOps -
Schulich School of Engineering, Sustainable Systems EngineeringBio-inspired design, Biomimicry, Information visualization, Data physicalization -
Schulich School of Engineering, Department of Mechanical and Manufacturing EngineeringCombustion Science and Fuel Research -
Schulich School of Engineering, Department of Civil EngineeringTravel behaviour and demand analysis, Consumer choice econometrics, Spatial econometrics, Stated preference survey methods, Transportation and land use policy, Energy and sustainability policy -
Schulich School of Engineering, Sustainable Systems EngineeringUrban Infrastructure Network Modelling, Predictive Modelling and Simulation, Sustainable Transportation Systems, Sustainable Smart Cities, Digital Twins, Climate Justice, Social Innovation in Engineering -
Schulich School of Engineering, Department of Chemical and Petroleum EngineeringCatalysis and sustainable development -
School of Architecture, Planning and LandscapeIndoor Environmental Quality | Health & Wellbeing | Comfort | Daylighting | Affordable housing | Aging in place, Indoor living environments and human health, Smart Building Technology & Automation, Inclusive design and policy -
Schulich School of Engineering, Sustainable Systems EngineeringContext-Based, Learner-Centered Engineering Education, Holistic and Integrated Engineering Design Curriculum, Embedding Systems Thinking, Design Justice, and Sustainability -
University of CalgaryHeat Transfer, Engineering Thermodynamics, Thermal design , CFD -
Schulich School of Engineering, Department of Chemical and Petroleum EngineeringSystems and life cycle assessment, Techno-economic analysis, Technology innovation, Greenhouse gas (GHG) mitigation, Carbon dioxide removal, Carbon capture and storage, Activities
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Schulich School of Engineering, Department of Civil EngineeringHydrological Modelling and Prediction, Geomatics Applications in Hydrology, Environmental impact of water-intensive industries, Water Governance and Adaptation Strategies, Activities -
Schulich School of Engineering, Department of Civil EngineeringEnvironmental engineering, Carbon Dioxide Removal (CDR), Bio-based economy, Systems analysis and strategic decision support -
Schulich School of Engineering, Department of Geomatics EngineeringAI and Machine Learning, Remote Sensing, Hyperspectral LiDAR Radar, Geospatial Data Science, Bio-/Geo-chemical/physical parameter extraction, Quantum computing -
Schulich School of Engineering, Department of Civil EngineeringEnvironmental Fluid Dynamics