Episode Overview: Vibration and acoustic performance are among the most technically challenging aspects of mass timber design. In this episode, Paul Becker and Kristina Rogers speak with Associate Sami Rahman about the relationship between vibration and acoustics in mass timber versus steel and concrete systems and what that means for design teams.

The conversation examines how mass timber’s lighter weight makes floor vibration performance more complex. Strategies that improve vibration performance, such as creating composite action between CLT and concrete topping, can negatively affect acoustic separation. Using the Bowers College of Computing and Information Science at Cornell University as an example, Sami explains how to strike the correct balance for optimal performance. They also look at why involving acoustics and vibration experts early in the design process can provide better, more efficient outcomes.

The discussion also explores options for successfully using mass timber in laboratories, research centers, and other spaces with sensitive equipment, such as manufacturing facilities. Sami discusses how advances in structural dynamics, finite element analysis (FEA), and validation of design models through field testing help us better understand and predict the behavior of mass timber structures. This will allow us to improve vibration-control design to allow mass timber to be used in more applications.

Key Insights

• Mass timber floors behave differently from steel or concrete. Because mass timber is relatively lightweight, vibration response is often governed by high-frequency impulse behavior rather than the low-frequency resonance commonly seen in heavier systems.
• Vibration and acoustics must be coordinated together. A design move that improves vibration performance can negatively affect acoustic performance, so both criteria need to be evaluated as part of the same design strategy.
• Modeling is stronger when calibrated with field data. Validating finite element analysis with heel-drop testing and impulse-response testing can help teams refine assumptions and better predict real-world mass timber performance.
• Vibration-sensitive buildings need early performance planning. Laboratories, research facilities, and other sensitive spaces require carefully considered framing strategies or localized enhancements to meet owner and equipment criteria.
• Early collaboration reduces late-stage redesign. For mass timber buildings, structural, acoustic, vibration, and architectural considerations should be integrated from the beginning rather than evaluated after the framing system is already set.

Topics Covered

• Mass timber vibration design
• Acoustic performance in mass timber buildings
• High-frequency floor response
• CLT floor systems and concrete topping
• Composite action and acoustic separation
• Finite element modeling for vibration analysis
• Field testing and model calibration
• Laboratory vibration criteria
• Tuned mass dampers and active mass dampers
• Early coordination among structural, acoustic, and vibration teams

The conversation explores the variables that influence fire safety, such as building height, floor area, occupancy type, amount of exposed timber, site constraints on fire department access, and neighboring exposures. Ali explains why mass timber requires a project-specific approach that combines layers of safety and risk-reduction strategies, especially for taller buildings.

Paul, Kristina, and Ali also discuss how forensic fire investigation; advanced modeling analysis; experimental research; and early conversations with owners, design teams, and AHJs can help build confidence in a mass timber fire strategy. The episode emphasizes robust design, clear communication, and informed decision-making as the mass timber industry continues to evolve.

Key Insights:

• Mass timber fire safety is project-specific. Building height, occupancy and egress, amount of exposed timber, site access, and neighboring exposures all influence how fire risk should be evaluated.
• Exposed timber requires careful fire strategy. Many projects want to showcase the wood structure, but exposed timber can affect fire dynamics and may require additional analysis or design measures.
• Prescriptive codes are the starting point, not always the full solution. Mass timber code provisions continue to evolve, but innovative projects may need a more detailed fire-engineering approach.
• Performance-based fire design can support approvals. When a project pushes beyond standard code limits, performance-based analysis can help define safety objectives, test assumptions, and clearly communicate the design rationale to AHJs.
• Fire engineering benefits from real-world evidence. Forensic investigation, experimental research, and analytical modeling help teams understand how timber buildings may perform under different fire scenarios.

Topics Covered

• Mass timber fire safety
• Performance-based fire design
• Exposed timber and fire dynamics
• Mass timber building code requirements
• Fire risk by height, occupancy, and building use
• Egress, suppression, and fire department access
• Authorities having jurisdiction (AHJs) and code approvals
• Forensic fire engineering and timber research
• Robust fire-safety strategies for innovative timber buildings

The conversation focuses on why fabricator input is especially important in mass timber construction. Because products, species, connection preferences, and manufacturing processes vary by supplier, early coordination helps teams design to the material’s strengths, streamline coordination, minimize late changes, and improve constructability.

Paul and Kristina also discuss options for connection design responsibilities and how that decision can impact design, fabrication and speed of erection. And they look at ways to adjust the design-bid-build delivery process – which doesn’t lend itself to design-assist – so it works more effectively for mass timber projects. Through examples including the Samuel H. Scripps Theater Center, the Roux Institute and Goldfinch Lofts, they explain how experienced teams collaborate to maintain flexibility, clarify performance expectations, and coordinate with suppliers to support successful delivery.

Key Insights:

• Early supplier involvement can improve mass timber efficiency. Bringing a supplier or fabricator into the process early helps the design team align the structural system with available products, material dimensions, and fabrication preferences.
• Design assist helps reduce uncertainty. Fabricator input gives engineers and architects a clearer understanding of manufacturing capabilities, connection preferences and erection methods before key design decisions are locked in.
• Connection design requires close collaboration between engineers and fabricators, no matter who performs the scope. In mass timber buildings, connections can influence member sizing, load capacity, structural geometry and coordination with architectural intent.
• DFMA is central to successful mass timber delivery. Designing for manufacturing and assembly helps teams move from an abstract structural concept to a system that can be fabricated, shipped, and erected efficiently.
• Complex geometry benefits from fabricator collaboration. Curved glulam, long-span members and non-rectilinear systems often require early input on curvature limits, splice locations, connection options, and shipping size constraints.
• Traditional design-bid-build can work, but it needs adaptation. When early supplier selection is not possible, teams may need clearer performance criteria, more conservative assumptions, and additional coordination after the fabricator is selected.
• Better communication leads to better cost and constructability outcomes. The episode reinforces that mass timber projects benefit when engineers, timber fabricators, detailers, and erectors are part of the same technical conversation early enough to influence design.

Topics Covered:

• Mass timber procurement strategies
• Design-assist for mass timber projects
• Early supplier/fabricator involvement
• Design-bid-build delivery for mass timber
• Mass timber connection design responsibilities
• Fabricator-led connection detailing
• Design for manufacturing and assembly, or DFMA
• Glulam roof geometry and curved timber systems
• Supplier selection
• Timber erection sequencing
• Constructability coordination
• Public, university and institutional procurement constraints
• Mass timber cost and schedule considerations

The discussion focuses on how the properties of mass timber require designers to think and work differently than they do on steel and concrete structures. Greater elastic shortening, long-term creep and moisture-related movement demand not only advanced structural analysis but also close coordination with façade, MEP and other building systems to ensure that all components can accommodate movement over time. This level of integration requires structural engineers to play a central role in integrating these systems.

The episode also explores the realities of construction, procurement and cost in tall mass timber projects. From rapid installation schedules to real-time problem solving in the field, success depended on continuous collaboration between the design team, contractor and fabricator. Lessons learned from Ascent emphasize the importance of early design clarity, detailed coordination and strong partnerships to reduce uncertainty and achieve competitive pricing. As the industry evolves, these insights are shaping how future tall timber buildings are conceived and delivered.

Inside the Episode Hero Image: Use an Ascent glamor shot

Key Insights:

• Ascent established a new precedent for tall mass timber. The project serves as a critical benchmark for code development, design strategies and future high rise timber buildings.
• Tall mass timber requires advanced understanding of structural movement. Greater elastic shortening, creep and moisture related effects must be accounted for across all building systems, not just the structure.
• The role of structural engineers is central to project success. Engineers are deeply involved in code strategy, fire performance, constructability and coordination across disciplines.
• Early coordination reduces risk and cost uncertainty. Well-developed design documentation and clear system integration improve contractor confidence and lead to more accurate pricing.
• Real time collaboration is essential during construction. Fast paced installation requires immediate problem solving and strong communication between field teams and designers.
• Procurement strategy impacts project success. Providing clear and detailed design information early helps manufacturers deliver more competitive and reliable pricing.
• Hybrid systems represent the next evolution of tall timber. Combining mass timber with materials like concrete can optimize performance, cost and constructability.

Key Hero Image: Use gif of the Ascent model coming together.

What You’ll Learn:

• Design and delivery process of Ascent MKE
• How mass timber design considerations differ from steel and concrete
• Vertical movement in mass timber
• IBC 2021 and strategies for code variances and AHJ approval
• Connection design and detailing best practices
• Accurate early timber pricing
• Hybrid timber systems

What You’ll Learn Hero Image: TBD Use one of the interior shots from the Ascent page.

A central theme is the importance of proactive and continuous coordination when working with proprietary systems. Engineers must invest significant time in understanding design assumptions, reviewing calculations and collaborating closely with manufacturers. Frequent communication, detailed submittal reviews and early engagement allow teams to build confidence in the system while ensuring it integrates seamlessly with architectural intent and other building systems.

The episode also examines how collaboration across the full project team influences success. Engineers act as a bridge between manufacturers, architects, and contractors, helping translate proprietary concepts into buildable solutions. When all parties are aligned and open to new approaches, proprietary systems can enhance both speed and efficiency.

Chris highlights how prefabrication of mass-timber components off-site is enabling faster on-site assembly with smaller crews. But this shift requires strong up-front coordination, particularly for MEP systems. Early collaboration and detailed planning become critical to fully realize the benefits of speed and efficiency. The conversation also explores the benefits of having the structural engineer take on the role of special inspector during construction.

The episode examines how mass timber can address broader industry challenges, including labor shortages and the need to accelerate housing delivery. As adoption grows, hybrid systems offer a scalable model for both affordable and market-rate housing.

* In the International Building Code (IBC), mass timber (or “heavy timber”) is categorized as Type 4 construction. Type 3 (“ordinary”) combines noncombustible exterior walls with combustible interior elements. Type 5 (“wood-frame”) uses conventional light-wood studs and joists with plywood sheathing.

A major focus is placed on how close coordination among all team members directly impacts project feasibility and cost. Open communication and collaboration among architects, engineers, manufacturers, erectors, and contractors early on can identify cost drivers, enabling the team to optimize the design to lower costs.

The episode explores strategies for working with jurisdictions to facilitate approvals for code variances, using the real-world example of Ascent. It also covers ways in which the use of mass timber reduces construction costs, offsetting the cost of the material itself.

Hosts Paul Becker and Kristina Rodgers talk with experts in mass timber analysis, design, and construction to uncover effective strategies, best practices, and lessons learned from a large portfolio of projects. They discuss ways the advantages of mass timber – sustainability, low embodied carbon, biophilic benefits, construction efficiency, and circularity – can be successfully incorporated into a widening array of projects, including commercial buildings, high- and low-rise residential, healthcare and labs, academic buildings, data centers, cultural and arts centers, sports and recreation, aviation facilities, and bridges and transportation infrastructure.

In this episode, hosts Paul Becker and Kristina Rodgers talk with Eli Gottlieb about how mass timber is shifting from a niche material to a mainstream building system. Successful timber projects require early planning around layout, spans, orientation, and standard panel dimensions to optimize material efficiency and erection speed. Close attention to these issues reduces the cost of mass timber buildings.

The conversation also explores timber’s potential for dramatic architectural forms and unconventional uses, such as pavilion roofs and bridges. These ambitious designs succeed when teams standardize where possible and collaborate closely with fabricators on connections and detailing.

Eli uses real-world examples to illuminate the conversation, including Princeton University’s Hobson College, the Samuel H. Scripps Theater Center at Hudson Valley Shakespeare, and the High Line Moynihan Connector bridge.

In Season Two, Mainstreaming Mass Timber, we talk with innovators who are pushing the limits of mass timber about the ways new technologies and creative design are making mass timber viable for more projects than ever before.

Thornton Tomasetti is an international multidisciplinary engineering and consulting firm that is channeling all its capabilities to tackle climate change. Technical experts from across the firm will share best practices and lessons learned over 12+ years of focusing on embodied carbon and how to lower the greenhouse gas emissions of their projects.