The Benefits of Concrete

Concrete is so integral to our communities because it is the only building material that cost-effectively delivers:

It is quite simply the most versatile building material on earth. Here are more details:

Lowest Carbon Footprint

Concrete’s unparalleled durability, energy efficiency and complete recyclability, combined with industry innovations such as lower carbon Portland-limestone cement, also known as Contempra, carbonated concrete or concrete cured with CO2 rather than water, all contribute to making it the lowest carbon building material over the lifecycle of a structure or pavement. Now, a new study by Canada’s renowned International Institute for Sustainable Development finds that up to 72% of the carbon emissions from wood products may currently be omitted from wood LCAs and that when these emissions are taken into account, concrete’s embodied carbon footprint could be up to 6% less intensive than that of wood products.

Strong, durable and low maintenance

Concrete lasts decades longer than alternative building materials, and actually gets stronger over time. This reduces the total cost of ownership as well as the environmental impact associated with more frequent rehabilitation or reconstruction.


Concrete doesn’t burn, rust, or rot. It is resistant to fire, wind, water, vibrations, and earthquakes, keeping people safer and reducing costs. In the aftermath of extreme weather events, concrete structures have proven to be the most resilient.


Concrete Buildings - Concrete’s ability to store energy (its thermal mass) helps moderate interior temperature conditions, reducing a building’s heating and cooling demands over its service life by up to 8% (see the research). Used in combination with technologies such as radiant floors and geothermal or hydronic heating and cooling systems, concrete enables energy efficiency improvements of 70% over the Model National Energy Code for Buildings (see some examples

see some examples
). And it improves a building’ “passive survivability” in the event services such as power, heating fuel, or water are lost — increasing comfort for occupants and minimizing energy demands for the city as a whole.

Concrete Pavements are also energy-efficient in several ways. Studies

show that over a 50-year period, the embodied primary energy required to construct, maintain, and rehabilitate concrete pavement is one third of that required for asphalt pavement. The rigid surface of concrete pavements helps reduce fuel consumption and related energy emissions by heavy trucks and other vehicles by up to 7%. And their light colour helps reduce the heat-island effect — which lowers cooling requirements — while also reducing exterior lighting requirements at night by up to 24%.


A totally inert substance when cured, concrete is literally emission-free and will not emit any gas, toxic compounds or volatile organic compounds.


While strong and functional when hardened, concrete’s plasticity when freshly mixed lets designers adapt it to whatever form, shape, surface, and texture they can imagine. Innovations such as ultra-high performance concrete (UHPC), photocatalytic concrete and pervious concrete are also enabling new and creative uses — and new ways to address a host of sustainability challenges.

Ideal for adaptive reuse

Because of concrete’s strength, sound attenuation, and fire resistance, concrete buildings can easily be converted to other occupancy types during their service life. Reusing buildings in this way can help limit urban sprawl and further contributes to the conservation of our resources and preservation of the environment.


Thanks to their durability, resilience, low maintenance requirements and energy efficiency, concrete structures reduce operating costs related to operational energy consumption, maintenance, and rebuilding following disasters. Insurance costs for concrete buildings during the construction and operating phases have also been shown to be significantly lower than for buildings constructed with combustible, moisture-sensitive materials.

Concrete pavements are also cost-effective on a first cost and lifecycle cost basis, requiring only a third of the maintenance a comparable asphalt road would require over a 50-year service life. 


Concrete can be recycled as aggregate — for use as sub-base material in roadbeds and parking lots, for gabion walls, as riprap to protect shorelines or in other applications — or as granular material, thereby reducing the amount of material that is landfilled and the need for virgin materials in new construction.

Produced locally

Concrete is typically manufactured within 160 kilometers of a project site, using local resources. This greatly minimizes shipping and pollution and makes a significant contribution to the local economy.