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Low Embodied Carbon Building Materials in Construction

In the global effort to combat climate change, the construction sector continues to account for a substantial portion of carbon emissions worldwide.

In this article, we explore how specifying low-carbon construction materials can help alleviate pressure on the industry whilst helping the planet and minimizing waste.

ERP
Alex Boury

by Alex Boury

General Manager, Access Construction

Posted 14/10/2024

Low Embodied Carbon Building Materials in Construction

The UN Environmental Program recently reported that the building and construction sector is by far the largest emitter of greenhouse gases, accounting for a staggering 37% of global emissions.

As the demand for new infrastructure and housing continues to rise, so too does the urgency to adopt sustainable practices within the construction sector and reduce total emissions.

At the forefront of this movement, low carbon building materials offer a promising solution to reduce the environmental impact of construction work.

Environmental Impact of Traditional Building Materials

Traditional building materials such as concrete, steel, and brick have long been staples in construction due to their strength and durability.

However, their widespread use comes at a significant environmental cost. The production of these materials involves high energy consumption as well as high levels of embodied carbon emissions.

Embodied carbon, such as that found in concrete, steel and insulation alone accounts for 11% of global annual emissions.

The processes used to manufacture these materials all play a part in the final embodied carbon figure assigned to a building.

These processes include:

  • Raw material extraction
  • Raw processing
  • Melting
  • Manufacturing
  • Transportation to site

As a result, organisations such as WorldGBC (World Green Building Council) report that, all new buildings, infrastructure and renovations should have at least 40% less embodied carbon by 2030, to meet current Net Zero aims.

 

Low Carbon Building Materials: Innovations and Impact

Aiming to reduce embodied carbon is one of the few practical steps the construction industry can make. By making better design choices and specifying low carbon building materials, specifiers can meet modern-day initiatives.

When choosing low carbon building materials, there are two main categories you should know: Carbon Sink Building Materials and Low Carbon Building Materials.

 

Carbon Sink Building Materials:

Carbon sink building materials have the unique ability to absorb and store carbon dioxide from the atmosphere, thereby mitigating greenhouse gas emissions.

Carbon sink building materials are primarily sourced from harvested wood products (HWPs), made from trees that sequester carbon through photosynthesis.

As a material, wood’s dry weight is comprised of almost fifty percent carbon. In comparison, the carbon content of approximately 350 liters of gasoline, equates to 1m³ of wood.

 

Examples Of Carbon Sink Building Materials:

  • Mass Timber
  • Hempcrete
  • Biobased Materials

Mass Timber: Also known as Cross Laminated Timber (CLT), is an eco-friendly alternative to concrete that can be used in floors, walls, ceilings, and roofs. In a simulation study where CLT panels were substituted for conventional concrete floors in steel building frames, projections over a 30-year period showed an average reduction of 50 million metric tons of CO2e, excluding the carbon sequestration benefits of the trees used to produce the timber.

Hempcrete: Also known as Lime Hemp Concrete (LHC), is gaining attention as a sustainable alternative to conventional concrete for certain applications, such as non-load-bearing walls. In terms of energy consumption and carbon emissions, it offers significant advantages. A recent study found that by using unfired binders instead of lime in LHC production, carbon emissions can be reduced by up to 90% compared to standard LHC.

Biobased Materials: Derived from renewable resources such as agricultural by-products and plant fibers, biobased materials like straw bales and cork have the potential to sequester carbon and reduce reliance on fossil fuels.

 

Low Carbon Building Materials:

Low carbon building materials focus on minimizing carbon emissions during their production and usage.

Low-carbon building materials include materials with low embodied energy and carbon emissions throughout their production, assembly, and transportation.

The definition of what constitutes low-carbon materials varies from person to person. Therefore, due diligence and research is required to ensure that the products you’re specifying are in fact low carbon building materials.

For instance, while steel and aluminum products are generally regarded as high-embodied carbon materials due to their carbon-intensive extraction and refinement processes, recycled metal products employed in new construction projects can be deemed low-carbon alternatives.

 

Examples Of Low Carbon Building Materials:

  • Recycled Materials
  • Low-Carbon Bricks
  • Green Tiles
  • Green Concrete

Recycled Materials: Utilizing recycled content reduces the need for raw material extraction and processing, consequently lowering carbon emissions. Materials like recycled steel, glass, and plastic contribute to circular economy principles.

Low-Carbon Bricks: Traditional brick manufacturing processes often involve high energy consumption and emissions. Low-carbon bricks utilize innovative production techniques and alternative materials such as using fly ash – fine glass powder made primarily of iron, silica, and alumina to minimize carbon emissions.

Green Tiles: Green tiles refer to roofing or wall tiles produced with environmentally friendly materials and processes. These tiles are designed to have a low carbon footprint, typically utilizing recycled content or sustainable materials in their production. Additionally, they may incorporate energy-efficient manufacturing techniques to further reduce emissions during production.

Green Concrete: Innovations in concrete production, such as using supplementary cementitious materials like fly ash and slag, aim to reduce the carbon intensity of concrete, a traditionally high-emission material.

 

Using Low Carbon Building Materials Responsibly

While integrating low carbon building materials is a pivotal step towards sustainable construction practices, it's equally crucial to ensure they are used responsibly. This includes implementing effective waste management techniques and prioritizing sustainably sourced materials, such as those sourced from Forest Stewardship Certification (FSC) forests.

 

Waste Management Techniques:

Effective waste management is essential to maximize the environmental benefits of low carbon building materials. Strategies include:

  • Recycling and Reuse: Implementing recycling programs on construction sites to divert waste materials, such as wood, metal, and plastic, from landfills. Additionally, promoting the reuse of salvaged materials in new construction projects minimises the demand for virgin resources.
  • Waste Reduction: Adopting efficient construction practices to minimize material waste during both production and construction phases. This includes accurate project planning, optimizing material usage, and reducing over-ordering of supplies.
  • Composting: Implementing composting programs for organic waste generated during construction activities, such as wood scraps and landscaping debris, to divert them from landfills and promote soil health.

Sustainable Sourcing of Materials: 

While low carbon building materials offer environmental benefits, their sustainability also hinges on responsible sourcing practices. Key considerations include:

  • Sustainable Forestry: Prioritizing materials sourced from sustainably managed forests certified by reputable organizations like the Forest Stewardship Council (FSC) or the Programme for the Endorsement of Forest Certification (PEFC). This ensures that timber and other wood-based products come from forests managed with environmental, social, and economic considerations.
  • Supply Chain Transparency: Collaborating with suppliers who prioritize transparency and accountability in their supply chains, ensuring that materials are ethically sourced and produced with minimal environmental impact.
  • Local Sourcing: Opting for locally sourced materials whenever feasible to reduce transportation emissions and support the local economy.

By prioritizing the specification of low carbon building materials and integrating responsible construction practices, we not only pave the way for a more sustainable future but help meet current industry net zero aims.

Incorporate Sustainability into Your Next Project With Access Coins ERP 

Ready to take your construction projects to the next level of sustainability? Access Coins is a comprehensive ERP software solution is designed to streamline project management processes, optimize resource allocation, and enhance collaboration—all whilst prioritizing sustainability. 

With Access Coins ERP, you can: 

  • Centralize Project Data: Keep all project information in one centralized platform, making it easy to track sustainability metrics and monitor progress towards environmental goals. 
  • Optimize Resource Allocation: Efficiently allocate resources, including materials, labor, and equipment, to minimize waste and maximize efficiency throughout the construction process. 
  • Monitor Sustainability Performance: Gain real-time insights into your project's sustainability performance, identify areas for improvement, and make data-driven decisions to drive continuous improvement. 

Contact us today to learn more about how Access Coins ERP can help you towards incorporating more sustainable practices into your future projects. 

Alex Boury

By Alex Boury

General Manager, Access Construction

With over a decade of experience working in construction software, Alex has worked with a number of Tier 1 international construction firms to aid their digital transformation.  

Alex has applied his two masters degrees in engineering to overseeing and strengthening the Access Construction software suite, building partnerships and leading growth to ensure Access provides a world-class solution for the construction sector.