RoofViews

Building Science

Sustainable and Resilience—Are they related, the same, or opposites?

By Thomas J Taylor

October 08, 2018

The words sustainable and resilience juxtaposed against a glass building.

Most people in the built environment community are aware that using and specifying sustainable and resilient materials and designs is "the right thing to do." There has been and continues to be industry discussions about the environment and climate change; sustainability and resilience are sometimes just assumed to address environmental and climate change concerns in ways that are "good." But sometimes, these words are used without really appreciating whether or not they are essentially the same, different, or in some way linked.

The built environment represents a large consumer of resources, both in terms of materials and energy. The U.S. Energy Information Administration estimates that residential and commercial/industrial buildings consume 40% of the energy used in the U.S. Of that, the majority is used for heating, air conditioning, ventilation, and lighting. Non-energy resource use, including material use, construction waste, operating resources such as water, and end of life demolition waste is far harder to estimate, but is significant. However, the construction market is estimated to be $1.231 trillion for 2018, versus a total gross domestic product of $20.412 trillion. This means the construction market represents around 6% of the U.S. economy.

Residential and commercial/industrial buildings consume 40% of the energy used in the U.S.

Due to the impact of the built environment on both energy use and resource consumption, it's important to reach a better understanding of sustainability and resilience. Are these terms the same, complimentary, or independent? This article will examine each in turn and then compare the two. As will be seen, they are not the same and, sometimes, can conflict in ways that are counter to goals generally regarded as "good."

Sustainable

This adjective generally means:

  • Able to be used without being completely used or destroyed.
  • Involving methods that do not completely use up or destroy natural resources.
  • Able to last or continue for a long time.

Sustainability (the noun) is the capacity for:

  • Human health and well being
  • Economic vitality and prosperity
  • Environmental resource abundance

So, the building designer who wishes to incorporate sustainability into buildings might ask:

  • Are materials safe for humans and the ecosystem?
  • Is this design energy and resource-efficient?
  • Is a material available or will its use today cause a shortage in the future?

Resilience

This noun generally means:

  • An ability to recover from or adjust easily to misfortune or change.
  • The ability to become strong, healthy, or successful again after something bad happens.

Putting this in terms of the built environment, resilience is the capacity to:

  • Overcome unexpected problems.
  • Continue or rapidly bounce back from extreme events.
  • Prepare for and survive catastrophes.

So, key questions for the building designer are:

  • Can a structure be occupied and functional after a severe storm or some other extreme environmental event?
  • Will occupants be able to function in the absence of utilities?
  • What reduction in occupational capacity is acceptable after an extreme environmental event?

Sustainable versus Resilient

To compare the two terms, it's instructive to examine some design choices. The schematic below shows some examples of choices that represent more or less of the two characteristics:

The following is a discussion of some of the examples shown in each of the quadrants:

Less Sustainable / Less Resilient

In the lower left corner, "Grid Only Power" refers to a building's reliance on grid electricity supply. The national grid gets about 17% of its power from renewable sources such as wind and solar. The remainder is from fossil fuels and nuclear and therefore today's grid power, while improving, can be regarded as less sustainable versus, for example, a grid that was essentially all supplied from renewable resources. From a building use perspective, grid-only power is likely the least resilient choice of energy since a building's power could be cut not just by an event locally but anywhere within the region. Properly designed and installed solar energy with storage, as indicated in the upper-right quadrant of the schematic, would be more resilient.

More Sustainable / Less Resilient

In the upper-left corner, "Zero Waste to the Landfill" typically refers to the production of a material that does not result in any waste being landfilled. Instead, any manufacturing scrap is recycled either back into the product or into other materials. The term can also refer to construction practices that recycle all waste. Eliminating waste by recycling is generally regarded as a sustainable endeavor but in no way does it impact a building's resilience in the face of future extreme events.

Less Sustainable / More Resilient

In the lower-right corner, "Large Reserves of Bottled Water" refers to a planning approach aimed at withstanding a loss of water due to some extreme weather event. Such water reserves could indeed be invaluable during such an outage, but plastic bottles are generally not viewed as being a sustainable choice. It's worth noting that while the loss of water might be viewed as a very unlikely possibility, it occurred in high buildings throughout New York City in the aftermath of Superstorm Sandy in 2012. In tall buildings, the water supply to higher floors and sometimes the entire building is totally reliant on electric pumps. Therefore, loss of grid power quickly leads to a loss of water supply.

More Sustainable / More Resilient

In the upper-right hand corner, "Solar with Storage" refers to the use of solar panels coupled with battery power storage to withstand temporary loss of grid power. Solar power is widely regarded as being more sustainable than fossil-fueled power plants, for example. However, solar power systems typically shut down during a grid outage to prevent the system from attempting to power the neighborhood. The addition of battery storage enables a system that would shut off from the grid and provide uninterrupted power for some time after the loss of grid power. The degree of resilience would depend on many factors including the size of the solar array, amount of battery storage, the power usage within the building, etc.

Sustainable versus Resilient — Conclusion

It should be clear from the discussion so far, that sustainable and resilient are two different considerations and are independent of each other. Simply because a material or design is sustainable doesn't mean that it is resilient and vice versa.

Simply because a material or design is sustainable doesn't mean that it is resilient and vice versa.

The following section examines sustainable and resilient choices for low-slope roofing.

Sustainable Roofing

Discussions about sustainable roofing are mostly about the materials used. Some materials used in the past, such as asbestos insulation, would be regarded as unsustainable given their potential for harm. But, given today's wide array of choices, how is a building professional able to make decisions as to whether a particular material is sustainable or not? There are many opinions and options, but LEED® v.4 provides a common baseline that can be useful in making decisions. LEED® contains a Building Product Disclosure & Optimization (BPD&O) section that encourages:

  • Use of products having an Environmental Product Declaration (EPD), this being an internationally accepted, verified, and published report focusing on the ways in which a product affects the environment throughout its life cycle.
  • A publicly available report from raw material suppliers which includes raw material supplier extraction locations, a commitment to long-term ecologically responsible land use, a commitment to reducing environmental harms from extraction and/or manufacturing processes, and a commitment to meeting applicable standards or programs voluntarily that address responsible sourcing criteria.
  • Disclosure of the material ingredients through documentation such as Health Product Declarations (HPD).

In addition, as part of the LEED® Building Design & Construction — Sustainable Site section, there are credits given for Heat Island Reduction through the use of cool roofing or reflective membranes.

Membranes

The following table summarizes the status of the major types of low-slope roofing membranes in terms of BPD&O and cool roof status:

BPD&O - Building Product Disclosure & Optimization

EPDM, while a popular membrane, is generally not used as a white version due to its added cost. Also, when the market share of the various membrane types is considered, as in the following chart, it's apparent that TPO should be examined closely for its sustainable characteristics.

The chart shows a projection over the coming years and it is clear that TPO has become the dominant low-slope membrane. Also, as older TPO roofs come up for replacement, it's possible that the long-term trend towards TPO will accelerate. Examining TPO in terms of sustainability shows:

  • TPO typically doesn't contain any "red list" materials.
  • TPO can be obtained with up to 35-year warranties, depending on type, installation, thickness, and manufacturer. Materials with long life cycles are widely regarded as being more sustainable.
  • TPO can potentially be recycled at the end of its useful life as a roof membrane.

Insulation

Since insulation is used to reduce long-term energy demand for heating and air conditioning, its use is generally considered sustainable. The status of the major insulation materials used in low-slope roofing in terms of BPD&O is shown in the following table:

BPD&O — Building Product Disclosure & Optimization. Certification and documentation depends on individual manufacturer.

As for membranes, it is instructive to examine the market share of each of these materials, as shown:

In examining polyiso more closely, it's apparent that it is generally a good choice especially when the non-halogen version is specified. The material has a low water vapor permeance, is thermoset (i.e., doesn't melt during fires), and isn't negatively affected by solvents.

Balance of System Any roof assembly consists of more than the membrane and insulation. The additional components necessary to complete any roofing system, depending on exact design, are discussed as follows:

Cover Boards — the use of gypsum boards can provide LEED¬Æ Materials and Resources credit. Similarly, high-density polyiso boards, when specified in the non-halogen version can provide LEED¬Æ BPD&O credit.

Adhesives — traditional solvent-based adhesives are still used in many regions, but tightening environmental regulations have led to increased use of water-based and low-VOC (volatile organic content) materials. There are few available with an EPD or HPD, however water-based and low VOC materials are regarded as being more sustainable versus solvent-based materials.

Fasteners — in terms of overall content, fasteners are a very small proportion of a roofing assembly and many might consider them to have an insignificant contribution to sustainability. However, in the case of coated plates that allow inductive heating attachment of the membrane, this enables most of the benefits of fully adhered systems to be achieved without the use of adhesives.

Resilient Roofing Sustainable roofing is mainly focused on material choices:

  • Content / how they are manufactured
  • Life cycle
  • Length of use / Durability

However, resilient roofing is concerned with how those materials are used together in a roof design to better protect against large and severe deviations from normal weather patterns. Such events can be:

  • High Wind / Storms — wind and storms of above-normal expectations require roof assemblies with enhanced wind uplift resistance. This requires care with design details as well as a good understanding of wind load fundamentals and design basics. As high wind events and storms increase in severity, it is worth considering the use of known designs that improve wind uplift resistance. An example would be specifying fully adhered membranes versus mechanical attachment.
  • Hail — data from the U.S. Department of Commerce shows hail damage to property as being economically very significant:

While long-term trends are debatable, there is a sense that a combination of changing climate combined with increased population densities in areas at risk are leading to a long-term trend toward more claims. Studies have shown that more conservative single ply roof assemblies, consisting of fully adhered fleece-back membrane over high-density polyiso cover boards that are also adhered can lower the risk of ice ball impacts. Furthermore, TPO designed for long-term weather resistance may provide longer-term protection against impact.

  • Loss of Heat — grid power brownouts and outages due to weather-related incidents have been trending upwards, according to the U.S. Energy Information Administration.

Electrical power outages, in turn, lead to a loss of building heat or air conditioning which can reduce or prevent functional business operations in affected buildings. From a low-slope roof design perspective, insulation and air barrier requirements can help reduce energy loss during power outages and thereby make a building more resilient. Insulation can be specified to go beyond code requirements but even seemingly minor changes in installation can improve its efficiency. For example, always making sure that insulation is installed in two layers with staggered joints helps reduce thermal loss through gaps. Also, specifying fully adhered membranes and adhering the top layer of insulation can reduce thermal bridging.

Sustainable Versus Resilient Roofing — in Conclusion

Sustainable roofing is mostly about material choices. Of today's common materials, TPO roofing membranes and non-halogen polyiso insulation are generally accepted as meeting sustainability requirements. For the balance of system materials, non-halogen high-density polyiso and gypsum cover boards also are considered sustainable materials. For securement, low-VOC and water-based adhesives are available as replacements for traditional solvent-based systems.

Resilient roofing enhances the ability of buildings to continue to function after extreme weather events.

Resilient roofing enhances the ability of buildings to continue to function after extreme weather events. It is mainly the roof assembly design that determines resiliency of the roof together with workmanship and quality of installation. As discussed in this article, there are many known designs available to improve on resiliency beyond a basic system that simply meets code requirements. Such systems can include fully adhered systems to increase wind uplift resistance , the use of fully adhered fleece-back membranes and adhered high-density polyiso cover boards to improve protection against impact, and increased insulation to help reduce heat gain/loss during power outages.

As a final note, it may be worth considering that many would argue that climate change might induce more extreme weather challenges than are planned for today. It might be important to consider adaptation strategies to improve resilience of the built environment toward future climate changes. Adaptation will be discussed in a future article. NOTE: This blog is for information purposes only. GAF does not provide professional design services. You should always consult with a design professional to determine whether the roofing system to be installed is suitable for the particular needs of your building.

Note: LEED®—an acronym for Leadership in Energy and Environmental Design™—is a registered trademark of the U.S. Green Building Council.

About the Author

Thomas J Taylor, PhD is the Building & Roofing Science Advisor for GAF. Tom has over 20 year’s experience in the building products industry, all working for manufacturing organizations. He received his PhD in chemistry from the University of Salford, England, and holds approximately 35 patents. Tom’s main focus at GAF is roofing system design and building energy use reduction. Under Tom’s guidance GAF has developed TPO with unmatched weathering resistance.

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This includes raw material supply, manufacturing, construction/installation, maintenance and repair, deconstruction/demolition, waste processing/disposal of building materials, and transport between each stage and the next. These embodied carbon phases are indicated by the gray CO2 clouds over the different sections of the life cycle in the image below.We often focus on "cradle-to-gate" embodied carbon because this is the simplest to calculate. "Cradle-to-gate" is the sum of carbon emissions from the energy consumed directly or indirectly to produce the construction materials used in a building. The "cradle to gate" approach neglects the remainder of the embodied carbon captured in the broader "cradle to grave" assessment, a more comprehensive view of a building's embodied carbon footprint.What is Operational Carbon?Operational carbon, on the other hand, is generated by energy used during a building's occupancy stage, by heating, cooling, and lighting systems; equipment and appliances; and other critical functions. This is the red CO2 cloud in the life-cycle graphic. It is larger than the gray CO2 clouds because, in most buildings, operational carbon is the largest contributor to total carbon.What is Carbon Dioxide Equivalent (CO2e)?Often, you will see the term CO2e used. According to the US Environmental Protection Agency (EPA), "CO2e is simply the combination of the pollutants that contribute to climate change adjusted using their global warming potential." In other words, it is a way to translate the effect of pollutants (e.g. methane, nitrous oxide) into the equivalent volume of CO2 that would have the same effect on the atmosphere.Today and the FutureToday, carbon from building operations (72%) is a much larger challenge than that from construction materials' embodied carbon (28%) (Architecture 2030, 2019). Projections into 2050 anticipate the operations/embodied carbon split will be closer to 50/50, but this hinges on building designs and renovations between now and 2050 making progress on improving building operations.Why Insulation?Insulation, and specifically continuous insulation on low-slope roofs, is especially relevant to the carbon discussion because, according to the Embodied Carbon 101: Envelope presentation by the Boston Society for Architecture: Insulation occupies the unique position at the intersection of embodied and operational carbon emissions for a building. 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By making our buildings more robust against wind uplift to meet updated standards, we are in effect making them less robust against the negative effects of hot and cold weather conditions.So, how bad is this problem, and what's a roof designer to do about it? A team of researchers at SGH, Virginia Tech, and GAF set out to determine the answer, first by simplifying the problem. Our plan was to develop computer simulations to accurately anticipate the thermal bridging effects of fasteners based on their characteristics and the characteristics of the roof assemblies in which they are used. In other words, we broke the problem down into parts, so we could know how each part affects the problem as a whole. We also wanted to carefully check the assumptions underlying our computer simulation and ensure that our results matched up with what we were finding in the lab. The full paper describing our work was delivered at the 2023 IIBEC Convention and Trade Show, but here are the high points, starting with how we set up the study.First, we began with a simple 4" polyisocyanurate board (ISO), and called it Case A-I.Next, we added a high-density polyisocyanurate cover board (HD ISO), and called that Case A-II.Third, we added galvanized steel deck to the 4" polyiso, and called that Case A-III.Finally, we created the whole sandwich: HD ISO and ISO over steel deck, which was Case A-IV.Note that we did not include a roof membrane, substrate board, air barrier, or vapor retarder in these assemblies, partly to keep it simple, and partly because these components don't typically add much insulation value to a roof assembly.The cases can be considered base cases, as they do not yet contain a fastener. We needed to simulate and physically test these, so we could understand the effect that fasteners have when added to them.We also ran a set of samples, B-I through B-IV, that corresponded with cases A-I through A-IV above, but had one #12 fastener, 6" long, in the center of the 2' x 2' assembly, with a 3" diameter insulation plate. These are depicted below. The fastener penetrated the ISO and steel deck, but not the HD ISO.One visualization of the computer simulation is shown here, for Case B-IV. The stripes of color, or isotherms, show the vulnerability of the assembly at the location of the fastener.What did we find? The results might surprise you.First, it's no surprise that the fastener reduced the R-value of the 2' x 2' sample of ISO alone by 4.2% in the physical sample, and 3.4% in the computer simulation (Case B-I compared to Case A-I).When the HD ISO was added (Cases II), R-value fell by 2.2% and 2.7% for the physical experiment and computer simulation, respectively, when the fastener was added. In other words, adding the fastener still caused a drop in R-value, but that drop was considerably less than when no cover board was used. This proved what we suspected, that the HD ISO had an important protective effect against the thermal bridging caused by the fastener.Next, we found that the steel deck made a big difference as well. In the physical experiment, the air contained in the flutes of the steel deck added to the R-value of the assembly, while the computer simulation did not account for this effect. That's an item that needs to be addressed in the next phase of research. Despite this anomaly, both approaches showed the same thing: steel deck acts like a radiator, exacerbating the effect of the fastener. In the assemblies with just ISO and steel deck (Cases III), adding a fastener resulted in an R-value drop of 11.0% for the physical experiment and 4.6% for the computer simulation compared to the assembly with no fastener.Finally, the assemblies with all the components (HD ISO, ISO and steel deck, a.k.a. Cases IV) showed again that the HD ISO insulated the fastener and reduced its negative impact on the R-value of the overall assembly. The physical experiment had a 6.1% drop (down from 11% with no cover board!) and the computer simulation a 4.2% drop (down from 4.6% with no cover board) in R-value when the fastener was added.What Does This Study Tell Us?The morals of the study just described are these:Roof fasteners have a measurable impact on the R-value of roof insulation.High-density polyisocyanurate cover boards go a long way toward minimizing the thermal impacts of roof fasteners.Steel deck, due to its high conductivity, acts as a radiator, amplifying the thermal bridging effect of fasteners.What Should We Do About It?As for figuring out what to do about it, this study and others first need to be extended to the real world, and that means making assumptions about parameters like the siting of the building, the roof fastener densities required, and the roof assembly type.Several groups have made this leap from looking at point thermal bridges to what they mean for a roof's overall performance. The following example was explored in a paper by Taylor, Willits, Hartwig and Kirby, presented at the RCI, Inc. Building Envelope Technology Symposium in 2018. In that paper, the authors extended computer simulation results from a 2015 paper by Olson, Saldanha, and Hsu to a set of actual roofing scenarios. They found that the installation method has a big impact on the in-service R-value of the roof.They assumed a 15,000-square-foot roof, fastener patterns and densities based on a wind uplift requirement of 120 pounds per square foot, and a design R-value of R-30. In this example, a traditional mechanically attached roof had an in-service R-value of only R-25, which is a 17% loss compared to the design R-value.An induction-welded roof was a slight improvement over the mechanically attached assembly, with an in-service value of only R-26.5 (a 12% loss compared to the design R-value).Adhering instead of fastening the top layer of polyiso resulted in an in-service R-value of R-28.7 (a 4% loss compared to the design R-value).Finally, in their study, an HD polyiso board was used as a mechanically fastened substrate board on top of the steel deck, allowing both layers of continuous polyiso insulation and the roof membrane to be adhered. Doing so resulted in an in-service R-value of R-29.5, representing only a 1.5% loss compared to the design R-value.To operationalize these findings in your own roofing design projects, consider the following approaches:Consider eliminating roof fasteners altogether, or burying them beneath one or more layers of insulation. Multiple studies have shown that placing fastener heads and plates beneath a cover board, or, better yet, beneath one or two layers of staggered insulation, such as GAF's EnergyGuard™ Polyiso Insulation, can dampen the thermal bridging effects of fasteners. Adhering all or some of the layers of a roof assembly minimizes unwanted thermal outcomes.Consider using an insulating cover board, such as GAF's EnergyGuard™ HD or EnergyGuard™ HD Plus Polyiso cover board. Installing an adhered cover board in general is good roofing practice for a host of reasons: they provide enhanced longevity and system performance by protecting roof membranes and insulation from hail damage; they allow for enhanced wind uplift and improved aesthetics; and they offer additional R-value and mitigate thermal bridging as shown in our recent study.Consider using an induction-welded system that minimizes the number of total roof fasteners by dictating an even spacing of insulation fasteners. The special plates of these fasteners are then welded to the underside of the roof membrane using an induction heat tool. This process eliminates the need for additional membrane fasteners.Consider beefing up the R-value of the roof insulation. If fasteners diminish the actual thermal performance of roof insulation, building owners are not getting the benefit of the design R-value. Extra insulation beyond the code minimum can be specified to make up the difference.Where Do We Go From Here?Some work remains to be done before we have a computer simulation that more closely aligns with physical experiments on identical assemblies. But, the two methods in our recent study aligned within a range of 0.8 to 6.7%, which indicates that we are making progress. With ever-better modeling methods, designers should soon be able to predict the impact of fasteners rather than ignoring it and hoping for the best.Once we, as a roofing industry, have these detailed computer simulation tools in place, we can include the findings from these tools in codes and standards. These can be used by those who don't have the time or resources to model roof assemblies using a lab or sophisticated modeling software. With easy-to-use resources quantifying thermal bridging through roof fasteners, roof designers will no longer be putting building owners at risk of wasting energy, or, even worse, of experiencing condensation problems due to under-insulated roof assemblies. Designers will have a much better picture of exactly what the building owner is getting when they specify a roof that includes fasteners, and which of the measures detailed above they might take into consideration to avoid any negative consequences.This research discussed in this blog was conducted with a grant from the RCI-IIBEC Foundation and was presented at IIBEC's 2023 Annual Trade Show and Convention in Houston on March 6. Contact IIBEC at https://iibec.org/ or GAF at BuildingScience@GAF.com for more information.

By Authors Elizabeth Grant

November 17, 2023

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