How To Reduce Embodied Carbon in Buildings and Why It Matters

Carbon emissions are a major contributor to climate change, and the built environment is responsible for approximately 40% of the world’s annual carbon emission. This is precisely why industry organizations and companies around the world are setting carbon reduction and net zero goals.  

A key source of carbon emissions for buildings, and by extension a major influence on carbon reduction goals, is embodied carbon.

What Is Embodied Carbon?

Embodied carbon refers to the carbon dioxide emissions resulting from the production, transportation, construction, maintenance, and end of life processes of building materials. It is one of two key sources of carbon from a building’s overall lifecycle carbon footprint – the other being operational carbon. 

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Carbon emissions from a building’s energy consumption – that is, energy resulting from activities such as the operation of elevators, lights, and air conditioning systems – are known as operational carbon.

Why You Should Reduce Embodied Carbon in Your Buildings

The changing climate has highlighted the need for the world to reduce its carbon emissions. Historically, the focus has primarily been on operational carbon for reducing overall carbon emissions. However, as both residential and commercial buildings are becoming more energy efficient, greater emphasis is being placed on reducing embodied carbon, as it remains a major source of emissions for the buildings sector. 

As a result, there are several reasons to prioritize reducing embodied carbon in buildings through the design and construction process. 

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Carbon emissions generated today, including the embodied carbon of buildings, will contribute to the increasing effects of climate change down the road, including extreme temperatures, more severe weather events, loss of biodiversity, impacts to our food systems, and increased droughts.

Role in Building Sustainability Standards

Reducing embodied carbon is rapidly becoming part of many building sustainability regulations and certification programs, including LEED, DGNB and others.

The World Building Council has set a goal for all new buildings: net zero operational carbon and a 40~ reduction in embodied carbon by 2030. Some standards and regulations include hefty fees for buildings that fail to meet them. Similarly, the Science Based Targets Initiative, which aims to help companies set climate targets and transition to a low-carbon economy, has recently released guidelines for the buildings sector including emphasis on reducing embodied carbon emissions. 

Boost Building Revenue

Reducing embodied carbon is a crucial component of developing sustainable, low carbon buildings. These buildings may be more marketable to customers as the public becomes more aware of the climate impacts from buildings, which can result in the ability to achieve rent premiums. Many prospective tenants are now making climate mitigation and resiliency a priority, leading them to seek out low and zero carbon buildings to call home and support their own sustainability objectives. 

Reduce Construction and Operation Costs

Reducing embodied carbon can offer building projects significant cost savings in several ways – a little bit of planning is all that’s required. Much of this relies on how embodied carbon reduction is achieved, which often includes: 

  • optimizing the structure, 
  • reducing the quantities of high-emitting materials used,
  • re-using building materials, 
  • selecting more sustainable, lower-carbon materials, and
  • sourcing building materials locally.

These activities save money in multiple ways, including by avoiding the purchase of excess materials and reducing material transportation fees. 

How to Calculate Embodied Carbon in Buildings

Changes in the climate and the resulting effects are major drivers behind decarbonization – of which reducing embodied carbon is a significant part. As developers, early planning and analysis are crucial to identify key opportunities to reduce embodied carbon – and this process starts with an estimate of your buildings’ embodied carbon.  

Whole Building Life Cycle Assessment 

A whole building life cycle assessment (LCA) looks at the quantities of materials and products used and their associated climate impact, from sourcing, through construction and use phase, and end of life disposal, to estimate the total embodied carbon of a building design.

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This helps create a baseline estimate that can then be used to identify and inform reduction measures. LCAs are helpful for examining different strategies and the effects they will have on reducing embodied carbon. For instance, after the baseline is established, further assessment can detail the impact of reducing underground parking,  optimizing the building structure, or selecting different building materials on the project’s total embodied carbon.

LCAs open the door to truly examine the carbon impacts of design decisions and make informed adjustments before construction begins.

Environmental Product Declarations

Environmental product declarations are a key ingredient in the development of an LCA. In addition to helping facilitate the procurement process, they help developers understand the impacts of individual products, such as a steel product or concrete mix, on overall embodied carbon. 

Ultimately, environmental product declarations give designers and developers transparency and allow them to make informed decisions at the product or material level, which can have a big influence when looking to reduce the building’s overall embodied carbon. 

How To Reduce Embodied Carbon in Buildings

We know embodied carbon is a major source of carbon emissions from buildings and the built environment as a whole and this has a significant impact on the climate. Thankfully, there are quite a few ways to build more sustainably and significantly reduce embodied carbon.

Design for Material Efficiency

Designing to ensure you use materials as efficiently as possible can go a long way in reducing embodied carbon as well as project costs. Designing an efficient structure is also a benefit. For example, aligning the structural system of the building may reduce or eliminate the need for transfer slabs, which require a large volume of high-emitting concrete materials. Structural optimization can help designers use materials more efficiently, leading to carbon and even cost savings. 

Build With Lower Carbon Materials  

Building with lower carbon materials has the potential to significantly reduce a building’s embodied carbon. Options include using low carbon concrete or even alternative structural systems like mass timber or hollow core slabs. Instead of XPS insulation, alternatives like NGX insulation can also reduce embodied carbon. Additionally, steel sourced from an electric arc furnace and made with a high recycled content can also lower the overall embodied carbon. 


When choosing alternative materials to build with, it is also worth considering their carbon storing ability. Responsibly sourced wood products often have a less carbon intensive manufacturing process and store carbon in their lifecycle as well. As they grow, trees remove carbon from the atmosphere and store it in their mass. This is referred to a biogenic carbon storage – where carbon is stored in biological material like wood. Ultimately, because trees pull CO2 from the atmosphere, wood products often have a lower carbon footprint. Of course, any wood used should be harvested from a sustainable forest and end-of life disposal should be carefully considered to ensure the greatest benefits.

Minimize Underground Parking   

Underground parking for residential buildings in urban environments is becoming less of a necessity as public transit systems are built out and become even more reliable. This is especially good news when looking to address embodied carbon in buildings and, ultimately, reduce a building’s embodied carbon.

An estimated 20 to 50% of concrete in a building is used below grade.

The use of concrete is often the highest when dealing with underground parking in residential buildings. Minimizing underground parking is so effective at reducing a building’s embodied carbon because it means using less carbon intensive materials, including concrete, rebar, and insulation. 

Moving Forward with Embodied Carbon Reduction

The increasing effects of climate change have highlighted the need to rapidly reduce carbon emissions more than ever. This is magnified even more when the extent of buildings’ contributions to global carbon emissions are considered. Efforts to reduce embodied carbon should begin with measuring and tracking these emissions as a first step in developing a comprehensive reduction strategy. 

Source: Taryn Green, RWDI, Technical Director

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