Early Mass Timber Collaboration: A Journey from Design Assists Pre-Construction through Construction
Course Overview In this session attendees will be taken through the evolution of the mass timber structure design for the Sam Centre at the Calgary Stampede. We will explore the varied forms of collaboration from design and pre-construction through construction to completion. During the talk the value of collaboration will be examined from a design assist trade to the early onboarding of a mass timber erector, to the engagement of a mass timber specialists examining topics from erection tolerances to moisture and construction protection, to storage procedures, to fire retardant impregnation, and the aesthetic and performance outcome of each. Particular attention will be paid to how the process of collaboration at the various stages aided the design and successful execution of the mass timber connection details. A tour of the project could also be offered given its proximity to the conference. The Sam Centre is a year-round immersive experience that brings the ‘world of the Calgary Stampede’ – past, present and future – to life through technology, story-making, and Western hospitality. The use of Mass timber was a key strategy in connecting to the history of the Stampede and its historic structures. Sam Centre is a linear volume characterized by a large horizontal pitched roof. The structure uses a repetitive hybrid steel frame with exposed mass timber beams and a Nail Laminated Timber Roof Deck, adding warmth to the interior and creating a distinct profile offering a modern yet durable nod to traditional barn construction. Creating deep overhanging soffits which mitigate heating and cooling loads, the roof also evokes the welcoming verandahs of traditional Alberta architecture. Learning Objectives Learn how design assist supported the design of the mass timber connections and how those details would be built to ensure the structure was built efficiently and effectively. Learn about the importance of bringing on a mass timber erector early in the design process to ensure that the construction system and any tolerances required are correctly captured in drawings. Understand the value of a collaborative approach between design team, consultants, trades, and building science team to ensure all facets of mass timber construction are noted across project phases. Course Video Speakers Bio Jeff Geldart, AAA, OAA Associate Diamond Schmitt Jeff Geldart believes having a thorough understanding of the client’s goals and objectives is critical to developing a design that best meets their needs and expectations. That understanding becomes the root of any great piece of architecture. If the building does not meet the needs of its occupants, then the rest is superfluous. Throughout his professional career Jeff has worked with both institutional and private sector clients. Some of his more notable institutional projects have included work with Wentworth County and Canada’s Department of Foreign Affairs and International Trade. One Developments, Lifetime Developments and Kylemore Communities are among his residential accomplishments. This broad and range of experience has allowed him to enhance his drive for achieving design excellence while at the same time rigorously working to consistently meet schedules, budgets, and ultimately project execution. Jeff demonstrates a phenomenal capability technically, aesthetically, and managerially on his projects. Since joining Diamond Schmitt in 2019, Jeff has worked as the Senior Architect on the Ottawa Public Library and Library Archives Canada Joint Facility and the Okotoks Arts and Learning Campus in Alberta. Jeff is currently based in Calgary. Mark Grimes, P.Eng, PMP Senior Project Manager EllisDon Mark Grimes is a Senior Project Manager at EllisDon, originally graduating from Trinity College Dublin with a degree in Civil and Structural Engineering – Mark moved to Canada in 2010 and has spent the last 15 years working primarily in Alberta on a wide range of projects ranging from highrise tower construction to luxury hydrotherapy spas.
Lessons from “The Timber City”
Course Overview The presentation explores the innovative approach undertaken by the municipality of Växjö, Sweden, which aligns sustainable construction practices with the development of smart cities. By leveraging wood as a primary building material, this strategy reduces environmental impact, promotes resource efficiency, and supports the circular economy. The presentation details the integration of prefabricated wooden elements and advanced technologies such as IoT, AI, and digitalization to optimize urban infrastructure and enhance the quality of life for residents. The strategic framework includes collaboration with industry stakeholders, the transition to open innovation, and the establishment of standards and regulations to support long-term sustainable development. The presentation also addresses the municipality’s role in fostering innovation and market opportunities, aiming to transform Växjö into a leading example of a smart, sustainable city. This study contributes to the broader discourse on urban sustainability, providing actionable insights for policymakers, architects, and urban planners committed to developing resilient and environmentally responsible urban environments. Learning Objectives Understanding Sustainable Construction Practices: Attendees will gain insights into the benefits of using wood as a sustainable building material, including its impact on reducing environmental footprints and promoting long-term urban sustainability. Integration of Technology in Urban Development: Participants will learn how modern technologies such as IoT, AI, and digitalization are transforming construction processes and contributing to the development of smart cities. Strategic Planning for Smart Cities: The presentation will provide knowledge on the critical components of a smart city, including energy efficiency, resource management, and the use of advanced technologies to improve the quality of life for residents. Collaboration and Innovation in Urban Development: Attendees will understand the importance of open innovation, collaboration among stakeholders, and the role of municipalities in facilitating sustainable development and market possibilities in the context of sustainable construction and smart cities. Course Video Speakers Bio Fredrik Lindblad Professor Linneaus University Fredrik Lindblad is an accomplished leader with a distinguished career in international business management, strategic development, and logistics. Throughout his career, Fredrik has held key leadership positions globally, including roles at Danzas, DHL, and as the Global Head of Supply Chain at Aramex. Most recently, he served as CEO of Växjö Linnæus Science Park, where he played a crucial role in forging strategic partnerships, driving business growth, and fostering innovation. In addition to his executive roles, Fredrik has held several board-level positions and has been actively engaged as an international consultant, working on projects for governments, NGOs, and non-profit organizations. Fredrik holds a Doctorate in Industrial Engineering and a Licentiate in Economics from Linnaeus University, where he also serves as an Associate Professor. He is a prolific author, with numerous publications in journals such as the Scandinavian Journal of Public Administration, Forest Products Journal, Management and Technology, Wood Material Science and Engineering, and Construction Management and Economics. His research has made contributions to the fields of logistics, supply chain management, and wood construction technology.
Green Construction through Wood
Course Overview Green Construction through WoodThe Green Construction through Wood (GCWood) program encourages the use of innovative wood-based building technologies in construction projects. The renewed program expanded its focus to fund innovative building solutions and schematic designs under key areas of interest including, but not limited to, prefabrication, modular buildings, retrofits, and design for disassembly/adaptability. Accelerating Mass Timber Adoption in Canada Regional experts from WoodWorks, representing jurisdictions from across Canada, offer insights into regional opportunities and lingering obstacles to mass timber adoption, and discuss the strategies developed and presented in the Mass Timber Roadmap recently published by FPAC, CWC, Energy Futures Lab and The Transition Accelerator. Learning Objectives Understand the purpose and impact of the Green Construction through Wood (GCWood) program, including its role in reducing embodied carbon, enabling innovation, and supporting Canada’s mass timber ecosystem. Identify key barriers and enablers affecting mass timber adoption in Canada, such as technical challenges, regulatory evolution, supply chain capacity, and regional policy differences. Identify regional opportunities and market pathways for expanding mass timber construction, incorporating insights from WoodWorks experts across Canada and the strategic directions presented in the Mass Timber Roadmap. Course Video Speakers Bio Jean-Francois Levasseur Director, Industry Relations & Innovation Programs Natural Resources Canada Graduating from the University of Ottawa’s Chemical Engineering program, Jean-Francois started his career in a variety of increasing roles in Kraft pulp mills, including mill process and environmental engineer positions. He then joined Environment and Climate Change Canada where he led on numerous aspects of environmental regulatory regimes applicable to Canada’s forest sector. At Natural Resources Canada since 2009, he has led in the design and implementation of various funding programs supporting strategic R&D, innovation and capital investments that accelerate the transformation of the Canadian forest sector towards the Bioeconomy: the Pulp & Paper Green Transformation (PPGTP); the Forest Innovation Program (FIP); the Investments in Forest Industry Transformation program (IFIT), and; the Green Construction through Wood program (GCWood). Together, these programs provided more than $1B to support energy efficiency improvements, green energy production, and the commercialization of innovative products, transformative technologies and new wood based green building and mass timber demonstrations. Scott Jackson Director of Conservation Biology Forest Products Association of Canada Steven Street Executive Director WoodWorks Ontario Shawn Keyes Executive Director WoodWorks BC Rory Koska Executive Director WoodWorks Alberta Simon Bellavance Technical Advisor Cecobois David Porter Program Coordinator WoodWorks Atlantic Tim Buhler Director – Programs and Operations Canadian Wood Council
FRAMEWORK for Success: Prefabricated Wood Systems and Design Innovation
Course Overview This presentation explores the transformative impact of prefabricated light wood frame construction systems in multi-residential development, focusing on VanMar’s FRAMEWORK methodology and its application in the new 150 Wissler Road project in Waterloo. FRAMEWORK is a highly efficient, panelized light wood frame system designed for buildings up to six storeys, delivering rapid, sustainable, and cost-effective construction that meets and exceeds energy and greenhouse gas reduction targets. The session will highlight VanMar’s extensive experience in affordable housing, the advantages of offsite prefabrication, and the collaborative process that accelerates project delivery. Learning Objectives Participants will understand the benefits of prefabricated wood frame construction for multi-residential buildings. Participants will understand the FRAMEWORK system’s approach to speed, cost-effectiveness, and sustainability. Participants will be shown how collaborative offsite construction methods accelerated the 150 Wissler Road project. Participants will learn strategies for overcoming design challenges and achieving efficiencies in fire walls, shafts, and acoustics. Course Video Speakers Bio Jordan Zekveld Director of Preconstruction VanMar Constrcutors ON Jordan is a construction and development professional with deep experience in estimating, preconstruction, and cost strategy for multi-unit residential projects. At VanMar Constructors, he helps developers, REITs, and non-profits bring condominium, rental, and affordable housing projects from concept to construction. Drawing on VanMar’s integrated design-build expertise, Jordan leads collaborative preconstruction processes that align design intent, feasibility, and cost efficiency. His experience spans concrete high-rise and innovative mid-rise wood-frame developments, including the Framework system — VanMar’s sustainable, fast, and cost-effective building solution. With a focus on clarity, constructability, and long-term value, Jordan works at the intersection of planning, design, and execution to help deliver housing that’s efficient, affordable, and built to last. Mike Philips Executive Director Ontario Structural Wood Association (OSWA) Mike Phillips has served as Executive Director of OSWA since 2008. Under his leadership, the association has evolved from a truss-fabricator-focused group into Ontario’s leading voice for structural wood component manufacturing. Today, the province is home to 70 certified truss plants and 40 wood-panel manufacturers, with engineered wood products now the preferred choice for floor systems. At the same time, Ontario’s building code has never been more prepared to accommodate advanced wood-construction methods. Mike is a strong advocate for the industrialization of construction and the expanding role of off-site building systems—critical drivers of wood construction’s future growth. Paul Marchesani Operations Manager Panelized Building Solutions Inc. Paul Marchesani is the Vice President of Panelized Building Solutions Inc., a family run business where he plays a key leadership role in driving operational excellence, strategic growth, and project execution across the company. Known for his strong work ethic, hands-on approach, and deep industry knowledge, Paul oversees day-to-day operations while supporting long-term planning that aligns with the company’s vision. Before joining Panelized Building Solutions, Paul held key roles in project management and operations within manufacturing and construction environments, where he oversaw production teams, implemented process improvements, and helped streamline workflow efficiencies. His ability to manage both people and complex technical projects made him a natural fit for leadership. Respected by colleagues, clients, and trade partners alike, Paul combines technical expertise with strong leadership, making him an essential pillar of the company’s continued success.
The Future of Tall: The Future of Cities
Course Overview Over the past two decades, tall buildings have enjoyed a major uptake in almost all major cities globally. But is the push for greater urban density and taller buildings creating habitats and patterns of life that are truly sustainability, in terms of social, cultural and economic sustainability, as well as the carbon equation? Through examples from around the world, this session outlines areas where the typology, and cities, need to develop. Learning Objectives Understand the sustainability challenges and opportunities in tall building design: Explore how social, cultural, economic, and environmental factors influence the development of high-rise structures and urban density. Identify innovative strategies for integrating mass timber and other sustainable materials in tall buildings: Learn how material choices impact carbon reduction, energy efficiency, and structural performance in high-rise construction. Analyze global case studies to evaluate future trends in urban development and tall building typologies: Gain insights into design approaches that promote livable, resilient, and sustainable cities. Course Video Speakers Bio Dr. Antony Wood CEO Antony Wood Consulting Dr. Antony Wood is the former President of the Council on Tall Buildings and Urban Habitat (CTBUH), responsible for leading the Council’s thought leadership, research, and academic initiatives. Prior to this, he was CTBUH chief executive officer (CEO) from 2006-2022. During his sixteen-year tenure as CEO, CTBUH significantly increased its outputs and initiatives across all areas globally. Wood’s PhD dissertation explored the multi-disciplinary aspects of skybridge connections between tall buildings. He is associate editor of the CTBUH Journal and serves on the editorial board of several other journals. He is the author of numerous books and papers in the fields of tall buildings, sustainability, and related fields. Wood has been conference chair and chair of the scientific committee at all CTBUH conferences since 2006. He has also presented at numerous conferences, and lectures regularly around the world.
Design Best Practices for Mid-Rise Light Wood Frame Structures
Course Overview Light wood frame (LWF) construction is an accessible, cost-effective, low-carbon solution for mid-rise multi-family buildings. This session will clarify fundamental differences in approach between traditional low-rise LWF construction and modern mid-rise construction methods. LWF is an attractive option for mid-rise development and participants will gain practical insights into design efficiencies, from meeting seismic demands and other key structural considerations to how engineered wood products and specialty hardware can be used to optimize design. The session will also explore prefabrication strategies, highlighting the challenges and opportunities offsite construction presents for streamlined, higher-quality construction. Whether attendees are new to mid-rise wood design or looking to optimize their next project, this session will share valuable information they can apply to their next mid-rise building. Learning Objectives Distinguish key differences between traditional low-rise and modern mid-rise light wood frame construction, including changes in design loads, seismic requirements, and code updates. Apply practical design strategies to optimize mid-rise wood structures—such as efficient stacked framing, engineered wood products, specialty hardware, and solutions for wood shrinkage and differential movement. Evaluate prefabrication and offsite construction methods for mid-rise projects, identifying both challenges and opportunities to improve construction quality, speed, and coordination. Course Video Speakers Bio Sean Henry Director – Mid-Rise, Principal Tacoma Engineers Sean is the Director of Mid-Rise and a Principal at Tacoma Engineers, bringing 20 years of structural engineering experience to the role. Since joining the firm in 2005, Sean has led the design of a wide range of building types, with a particular focus on mid-rise developments including multi-family, seniors and affordable housing projects. He is especially recognized for his expertise in light wood frame construction with multiple projects designed and built since the adoption of 6 storey wood framed buildings in Ontario. He also has extensive experience with cold-formed steel, structural steel, reinforced concrete, precast, and concrete block building systems. Sean focuses on delivering practical, efficient structural solutions that support design intent while meeting the demands of constructability and cost-effectiveness.
Exploring the Feasibility of Point-Supported Mass Timber for Tallwood Construction
Course Overview This session examines the growing potential of point-supported mass timber systems in tall building construction, contrasting them with traditional timber framing and conventional steel and concrete approaches. It highlights regulator advancements, the role of mass timber in addressing mid-density housing needs, and the structural fundamentals of gravity and lateral systems. Through cost and schedule comparisons, design principles like bi-axial bending and punching shear, and insights from ongoing Canadian codification efforts, the presentation offers a comprehensive overview supported by real-world projects such as VAHA Burrard and BCIT Tall Timber. Learning Objectives Evaluate the opportunities and constraints for point-supported mass timber when compared to traditional timber framing schemes. Analyze the schedule and cost benefits of point-supported mass timber systems versus steel and concrete in tall construction projects. Explore state-of-the-art design methodologies and ongoing efforts towards codification in Canada. Course Video Speakers Bio Carla Dickof, P.Eng., M.A.Sc. Associate Principal | Director of Research & Development Fast+Epp Carla Dickof is the Associate Principal & Director of Research and Development at Fast + Epp, where she leads the Testing Team at Fast + Epp’s R&D hub, Concept Lab, and uses the data gleaned from research programs to regularly contribute to academic journals and conferences. Carla completed her Master’s degree studies at the University of British Columbia, where her thesis research focused on hybrid systems, specifically those combining steel and mass timber (CLT). Her experience as an engineer spans commercial, recreational, educational, and residential projects – and, since joining Fast + Epp in 2012, Carla has gained a robust fluency in all major building materials, including concrete, steel, light-framed wood, heavy timber, and mass timber. Her understanding of building physics and materials brings invaluable insights to her projects. Alejandro Coronado, P.Eng. Technical Advisor WoodWorks BC Alejandro Coronado is a Technical Advisor with a multidisciplinary background spanning contracting, supply, and consulting engineering. With both a Diploma and a Bachelor’s Degree in Structural Engineering from BCIT, Alejandro began his career in single-family residential design and steadily advanced to contribute to landmark projects such as the Centre Block Base Isolation at Parliament Hill, the UBC Museum of Anthropology Great Hall Renewal, the Royal BC Museum PARC Campus, and a mass timber campus in Silicon Valley. Initially drawn to mass timber for its expressive architectural potential, Alejandro quickly recognized its broader value in addressing today’s social and environmental challenges. Through many years of hands-on experience, Alejandro has become a champion for sustainable construction and simple yet effective structural solutions.
Design and Construction of Permanent Wood Foundations
Course Overview This course will provide guidance on the design and construction of permanent wood foundations (PWF) based on the Canadian standard CSA S406-16 – Specification of Permanent Wood Foundations for Housing and Small Buildings. Topics will include site selection, backfilling, PWF floor systems, air and vapour barriers, insulation techniques, crawl spaces, and design considerations for high wind and seismic zones. The course will give attendees a comprehensive overview of the structural and building science requirements for designing and constructing PWF systems. Learning Objectives History of PWF construction. Wood preservatives and material requirements for PWF. Overview of pertinent design and construction aspects of PWF. Standardization of PWF as per CSA S406.
Understanding Glulam: The structural and architectural capabilities of mass timber
Course Overview In this course, you’ll gain insight into the design and manufacturing considerations involved in using glulam in buildings. As one of the oldest mass timber products used in Canada, glulam offers exceptional flexibility and can be incorporated into a wide range of building types—particularly where curvature and expressive geometry are key. Presenters will outline design and manufacturing strategies for creating efficient structures, showing how glulam can be used not just as columns and beams, but as the primary structure in today’s innovative buildings—whether architecturally driven or focused on value and efficiency. They will also cover the availability of glulam products across Canada and explain how to maximize the value of the timber used. Practical tips will be shared to help designers and specifiers take full advantage of glulam’s attributes in a cost-efficient way. Learning Objectives Participants will learn the design strategies employed when using curvature and geometry in buildings and gain an understanding of what is possible with expressive architecture. Participants will understand the practical constraints of glulam manufacturing, including how to approach the design and specification of glulam members. Participants will learn how different wood species and strength grades are applied in glulam design, and how to use them efficiently for optimal performance. Participants will understand how geometry, fire ratings, and member layups influence the cost-efficiency and design potential of glulam systems. Course Video Speakers Bio Andre Lema Manager of Business Development Western Archrib Andre Lema, a seasoned professional in the wood industry, brings decades of experience and expertise. Starting as a carpenter and advancing through a degree in Construction Engineering at NAIT, Andre has been instrumental in driving the success of Western Archrib. His passion for wood and dedication to fostering client relationships have made him a key figure in the industry. Alejandro Coronado, P.Eng. Technical Advisor WoodWorks BC Alejandro Coronado is a Technical Advisor with a multidisciplinary background spanning contracting, supply, and consulting engineering. With both a Diploma and a Bachelor’s Degree in Structural Engineering from BCIT, Alejandro began his career in single-family residential design and steadily advanced to contribute to landmark projects such as the Centre Block Base Isolation at Parliament Hill, the UBC Museum of Anthropology Great Hall Renewal, the Royal BC Museum PARC Campus, and a mass timber campus in Silicon Valley. Initially drawn to mass timber for its expressive architectural potential, Alejandro quickly recognized its broader value in addressing today’s social and environmental challenges. Through many years of hands-on experience, Alejandro has become a champion for sustainable construction and simple yet effective structural solutions.
Architectural Assemblies Simplified: Understanding Structural Grids: Acoustics and Envelopes in Wood Buildings
Course Overview This session will help you to formulate effective floor and wall assemblies when designing wood structures, both light wood frame and mass timber. Discussion will cover typical fire ratings and strategies, acoustic performance of different assemblies and effective strategies for weather-tight exterior envelopes. Background on typical structural assemblies for different grid sizes will help you understand how to effectively develop complete assemblies when designing timber buildings. Learning Objectives Participants will understand how to formulate effective floor and wall assemblies for wood structures, including both light wood frame and mass timber, to optimize performance and design efficiency. Participants will understand typical fire ratings and the acoustic performance of various assemblies and gain strategies to enhance the safety and comfort of wood buildings. Participants will learn how to design weather-tight, high-performance exterior envelopes for wood buildings. Participants will discover typical structural assemblies for different grid sizes and learn how to effectively develop complete assemblies when designing timber buildings. Course Video Speaker Bio Michael Wilkinson Principal and Senior Building Science Engineer RDH Michael Wilkinson is a Principal and Senior Building Science Engineer at RDH. He has provided consulting services across a range of building typologies with a focus on high performance and innovative building projects including those that are Passive House, mass timber, and volumetric modular. Michael has also been involved in numerous research projects including product development and performance monitoring and is the lead author of several guideline documents for government agencies and building enclosure product manufacturers. Additionally, Michael is a part-time instructor at the BC Institute of Technology where he teaches building science and construction technology classes. Derek Ratzlaff, P.Eng., Struct.Eng., PE Technical Director, WoodWorks BC Canadian Wood Council Derek began his career in the wood industry in high school working on single and multi-family light wood construction, after university and almost 20 years of structural consulting experience, Derek has worked in all types of wood construction and played key roles in the delivery of iconic BC wood structures, the Richmond Olympic Oval and Grandview Heights Aquatic Centre. He brings his experience in design and construction to support the industry as the Woodworks BC Technical Director.
Advancing North American Mass Timber Projects: Harnessing the Strength of Local Expertise
Course Overview As global adoption of mass timber construction accelerates, a growing number of solutions are available in the marketplace that can contribute to the success of your project. This session, presented by Simpson Strong-Tie, will explore some of the unique challenges faced by North American projects and some of the domestically developed solutions available to meet those challenges. Learning Objectives Understand the need for greater tolerance on concealed beam hangers, the importance of ensuring connectors are easy to install, and the specific requirements for large elements in North American buildings. Understand the advantages domestic suppliers can bring to your project, including the rapid delivery of hardware to job sites. Learn about the necessity for effective installation tools and processes tailored to the scale of large North American projects. Learn about the need for effective moisture mitigation and the systems and strategies that can prevent unnecessary exposure of mass timber to the elements during construction. Course Video Speaker Bio Adrian Mitchell Chair of Simpson’s internal Mass Timber Focus Market Committee Simpson Strong-Tie Adrian is a mass timber and off-site business specialist with a principal focus on the rapidly expanding mass timber segment, for which he serves as Chair of Simpson’s internal Mass Timber Focus Market Committee. Adrian has spent the bulk of his 20-year career in the off-site, mass timber, and modular spaces, primarily as a business development leader and private consultant. With professional experiences ranging from heavy civil, oil and gas, high-end custom homes to large-scale mass timber missed-use projects and artificial intelligence in BIM, he has a unique and well-rounded background in wood and steel applications in off-site construction. Adrian is a native of Vancouver, Canada, and a graduate of the British Columbia Institute of Technology’s School of Business, he enjoys all the typical Canadian pastimes like playing hockey, building things from wood, and mountain biking.
A Zero Carbon Hybrid Wood Supertall Future
Course Overview With buildings generating 40% of global carbon emissions, we need to achieve net-zero by 2050 to meet the Paris Agreement target and limit global warming to 2°C. Timber sequesters an average of 1.9 metric tons of carbon-dioxide equivalent emissions per cubic meter (Sathre & O’Connor, 2010). While a purely mass timber tall building may not be the most cost-efficient solution, a hybrid structure can maximize the overall use of wood by volume in the most cost-efficient manner. Floor systems in buildings contribute as much as 73% of the environmental impact of a high-rise building’s structure (Lankhorst et al., 2019), making them an excellent target for reducing embodied carbon. DIALOG’s patent- pending Hybrid Timber Floor System (HTFS) takes advantage of the benefits of cross-laminated timber (CLT) combined with pre-stressed concrete to achieve a 12-metre column-free span. The HTFS is proposed as part of our Hybrid Timber Tower, a 105-storey mixed-use prototype that is being evaluated and tested by DIALOG and EllisDon. The prototype structure consists of the hybrid timber floor, combined with a concrete core and an external steel frame. Fire safety is achieved in the floor panels as the exposed wood chars to form a protective layer, while the non-combustible concrete and steel band continues to support the panel. The exposed CLT panels also provide a biophilic appeal, which has shown to support cognitive function as well as physical and psychological well-being (Vidovich, 2020). DIALOG, EllisDon, FPInnovations and other partners have completed the first phase of small-scale testing on over 40 panels. We are scheduled for fire testing of the panels in Ottawa with NRCan this fall with full scale testing of the 12-meter panels starting in late 2022. Learning Objectives Describe how hybrid mass timber systems—such as the Hybrid Timber Floor System (HTFS)—reduce embodied carbon and support zero‑carbon goals in high-rise, mixed-use developments. Explain the structural, fire safety, and performance characteristics of hybrid CLT–concrete floor assemblies, including how charring, concrete bands, and steel elements contribute to long-span capability and code compliance. Evaluate the role of multidisciplinary research, prototyping, and large-scale testing in validating hybrid timber technologies for supertall applications, including their impacts on sustainability, biophilia, and cost efficiency. Course Video Speaker Bio Craig Applegath, BSc, BArch, MArchUD, PPOAA, AIBC, NSAA, AIA, FRAIC, LEED® APBD+C Founding Partner & Architect DIALOG Craig Applegath is the founding principal of DIALOG’s Toronto Studio, and a passionate designer who believes in the power of built form to meaningfully improve the wellbeing of communities and the environment they are part of. Since graduating from the Graduate School of Design at Harvard University with a Master of Architecture in Urban Design Craig has focused his energies on leading innovative planning and design projects that address the complex challenges facing our communities, as well as on his advocacy of sustainable building design and urban regeneration and symbiosis. Craig’s area of practice includes the master planning and design of institutional projects, including post secondary education, healthcare facilities, as well as the design of innovative mixed-use- facilities. Craig was a founding Board Member of Sustainable Buildings Canada, a Past President of the Ontario Association of Architects, and the current moderator of SymbioticCities.net. Craig has lectured or taught at Harvard, the University of Toronto, the University of Waterloo, as well as at many professional and sector related conferences around the world. In 2001 Craig was made a Fellow of the Royal Architectural Institute of Canada for his contributions to the profession of architecture. In 2017 he was presented with the OALA Honourary Membership Award for his contributions to the cause of landscape architecture in Ontario. Neel Bavishi, PEng, CEM Building Performance Analysis, Associate DIALOG Neel is passionate about applying the art and science of building performance simulation and data-driven design to produce positive outcomes for the built environment. He embraces holistic solutions that minimize the environmental impact of building assets while providing enhanced value to building owners, developers, policymakers, and designers through improved well-being and reduced total cost of ownership. Neel believes that an integrated and collaborative approach that incorporates diverse perspectives is essential for delivering high-performance buildings. A mechanical engineer by training, Neel is well-versed in whole-building energy modelling for both new and existing buildings and lifecycle cost analysis, design optimization, and data visualization. His experience includes developing energy models for green building certification programs, carbon-neutral retrofit studies and district energy strategies, and the development of net-zero energy and emissions policies and standards for municipal, provincial, and federal government bodies. His projects span various asset classes, including recreational facilities, commercial high-rise towers, multi-unit residential buildings, hospitals, data centres, and transit facilities. He is a licensed Professional Engineer in the province of Ontario and is a Certified Energy Manager. Cameron Ritchie, PEng, PE, PhD, BSE Structural Engineer, Associate DIALOG Cameron is an Associate on the Structural Engineering team in DIALOG’s Toronto studio. Since graduating with a PhD from the University of Toronto, Cameron has acted as a structural design engineer and project manager across a variety of sectors and project types, including healthcare, institutional, government, and retail. He has experience in all stages of a project delivery, from feasibility studies through construction administration and management. Cameron is DIALOG’s project manager for the hybrid timber floor system (HTFS) research program, working closely with industry partners EllisDon. He is passionate about exploring mass timber wherever possible as a sustainable solution to our building needs.
