By Sean Mowbray
Concrete forms the backbone of modern economies and societies: Roads, runways, homes, hospitals, banks, skyscrapers, sewers — just about any infrastructure you can imagine — depend on it. And as the global population grows, with rural people rushing to mega-cities for work, much more will be produced and poured.
Consequently, concrete is one of the most widely used materials on Earth, with its outdated linear “take-make-waste” production model making it one of the most environmentally harmful.
Manufacturing fresh concrete requires huge sums of extracted material, sucks up colossal amounts of water, creates clouds of unhealthful air pollution, and requires massive amounts of energy — fueling climate change. Cement alone accounts today for as much as 8% of global CO emissions.
Even more worrisome, scientists warn that concrete is significantly contributing to the destabilization of Earth’s planetary boundaries, helping promulgate a “triple crisis” of climate change, pollution and biodiversity loss — with the transgression of even just one of these boundaries potentially posing an existential threat to life as we know it.
It’s estimated that around 30 billion tons of concrete now gets used each year, already posing huge extraction, pollution and greenhouse gas emission risks, even as production surges in the Global South as the construction industry ramps up. “That starts looking like quite an enormous pressure on our planetary boundaries,” says Sophus zu Ermgassen, a postdoctoral researcher at the University of Oxford.
With the bulk of future demand coming from developing countries to improve substandard infrastructure and help raise living standards, there’s an urgent need now to find ways to reign in the harm caused by outmoded production methods and prevent soaring emissions, say experts.
Circular solutions are urgently needed to address environmental threats at multiple points along the cement and concrete supply chain, say experts such as Jonathan Duwyn, a buildings and construction specialist with the UN Environment Programme’s Climate Change Division. That means converting production reliant on fossil fuels to renewable energy, and finding cleaner ways to make concrete, while also minimizing its use by exploring alternative construction materials, methods and design models. Other circular economy approaches are needed to reduce concrete waste by maximizing the recycling and reuse of building materials.
Producing concrete for buildings and infrastructure puts pressure on multiple planetary boundaries, a series of nine global limits that experts say provide a “safe space” for humanity. Six of these — climate change, biodiversity integrity, nitrogen and phosphorus emissions, novel entities (pollution by synthetic materials), freshwater change, and land system change — are already crossed. Image by bepart64 via Pixabay.
Environmental impacts of cement and concrete
Principal among concrete’s impacts is its “colossal” contribution to climate change-causing emissions, say experts. Most of this huge carbon release is attributable to the manufacture of cement, a binding agent made by super heating and chemically altering limestone and clay. Cement is an essential ingredient in concrete, which is a mix of this binding agent, plus water, sand, gravel and stone aggregate).
Manufacturing Portland Cement, the most common form used today, requires heating immense kilns, usually stoked with coal and coke, to above 1,400° Celsius (2,552° Fahrenheit), energy consumption that accounts for 40% of cement’s carbon footprint. However, the thermochemical process that decomposes limestone to create clinker — a core component of cement — emits the majority of emissions; it is a process that cannot be avoided.
Other climate change-fuelling and potentially harmful pollutants released during production include nitrogen oxide, sulphur dioxide, and carbon monoxide, all of which have major impacts on public health.
A 2023 study found that carbon emissions from cement production in developing countries (even excluding China) could reach 3.8 gigatons by 2050, compared to around 0.7Gt in 2018. This tremendous surge in greenhouse gases alone could consume a massive amount of humanity’s remaining carbon budget to keep the world within 2° C (3.6° F) of warming; a planetary boundary which if crossed will have grave global consequences, says study co-author Dabo Guan, professor in climate change economics and the low carbon transition at the University College London.
Cement is a core ingredient of concrete and accounts for around 8% of global CO emissions. Companies are investing in a range of solutions to cut those emissions. Experts say that public procurement of infrastructure has a key role to play in these reductions, as governments can prioritize the use of “low carbon” solutions when contracting for new building projects. Image by Leeroy Agency via Pixabay (Public domain).
It’s estimated that buildings and construction account for around 21% of global carbon emissions, according to the U.N. Environment Programme (UNEP). Manufacturing of construction materials, such as cement and concrete, accounts for around 11% of that figure. A recent UNEP report notes that the world will need to implement a package of efficiency and technological solutions to reduce the sector’s environmental footprint. Image by wal_172619 via Pixabay (Public domain).
Demand from South Asia, India and Africa for cement and other emissions-intensive materials is going to be huge, he says: “There’s going to be a significant amount of emission space required by developing countries, and that’s simply to improve living standards.”
But the challenge now is not simply reigning in cement and concrete’s carbon footprint. Experts highlight the significant water burden for producing concrete; it accounts for around 9% of water consumed by industry globally. Of special concern, a 2019 study found that significant demand for construction-based water withdrawals will occur in water scarce regions by 2050.
These global impacts will be compounded by others: A host of materials need to be extracted from the earth to produce both cement and concrete, leading to land use change, water and air pollution, coastal erosion, and biodiversity impacts — a reality scientists are only beginning to grapple with00230-X).
Research indicates that quarrying for construction minerals — includingsand, stone and gravel — poses a threat to at least 1,000 species planetwide, according to Aurora Torres, an ecology and sustainability researcher at the University of Alicante.
“We don’t have a precise estimate of the number of species or the total biodiversity impacts of this activity,” she notes. “Sometimes what we see is that the direct impacts associated with the extraction are relatively localized, but those associated with erosion, air pollution and water pollution can travel larger distances.”
It’s estimated that around 50 billion tons of sand is used annually for construction, generating an array of environmental problems and social challenges. Research indicates these activities take a toll at the ecosystem level, and with human health by degrading air and water quality, and even influencing infectious disease spread in sand mining areas.
A cement factory in Denmark. The industry’s climate change-fueling emissions are a major concern, but making cement and concrete is also associated with other environmental impacts including high water use, direct and indirect biodiversity impacts, and pollution. Cement plant emissions of fine particulates, nitrogen oxide, sulphur dioxide and carbon monoxide have been linked to health issues for workers and communities near the factories. Image by astrid westvang via Flickr (CC BY-NC-ND 2.0).
Experts note that massive demand for sand is unsustainable and linked to multiple environmental and health impacts. It’s estimated that demand for sand will increase by around 45% from 2020-60, and by 300% in low to middle income countries. “The construction sector, as the primary consumer of sand, must adopt sustainable practices, reduce sand use, and seek alternative materials to mitigate the environmental impacts of sand mining,” says researcher Rangel-Buitrago at the Universidad del Atlántico, Colombia. Image by Jerzy Gorecki via Pixabay (Public domain).
Health concerns
While scientists warn urgently about cement and concrete’s climate footprint, they also note other important localized concerns. Poorly regulated cement plants contribute significantly to air pollution, emitting a host of harmful pollutants including heavy metals and particulate matter, with production also estimated to contribute to around 10% of global mercury emissions, or 2,200 tons each year.
“A lot of focus is on how to mitigate [cement’s] climate change impacts,” says Christopher Oberschelp, senior researcher and lecturer at ETH Zurich. “But we’re forgetting that we’re also having other very big problems in terms of human health” connected to its production.
In 2020, scientists estimated that, along with climate impacts, producing concrete causes around 5.2% of particulate emissions smaller than 10 microns and 6.4% of particulate emissions smaller than 2.5 microns; these tiny particles can penetrate deep into the lungs, so are associated with a host of health problems. The researchers calculated that the global climate and health cost of concrete equates to $335 billion per year. That cost will almost certainly rise as new quarries are dug and cement plants are built in the poorly regulated developing world.
These health concerns extend from workers’ exposure at mines , quarries and cement plants, and beyond to surrounding communities, says Phoka Rathebe, associate professor of environmental health at the University of Johannesburg.
Research by his team linked cement plant workers’ exposure to the development of chronic obstructive pulmonary diseases, while he notes multiple other studies have found a host of respiratory illnesses and a range of health impairments connected to production. Cement plants also raise questions of environmental justice, with research showing they are often disproportionately sited in low income communities of color in the United States for example.
A 2019 review paper notes that cement plant pollutants may have a “toxic activity on respiratory airways, reducing the dynamic lung function, increasing the risk of respiratory symptoms and diseases with a possible carcinogenic effect,” though that study also underlined issues with many studies. Another paper, for example, noted that pollution problems may be specific to individual facilities, but not at others, and emphasized that targeted research is needed in developing countries, particular those in Africa where there’s a dearth of information on the industry’s health impacts.
Oberschelp says existing technology could reduce air pollution and health impacts by minimizing and capturing pollutants. But the upgrade and modernization of cement plants is lagging, particularly in developing countries. “One good thing about this is that [because these impacts are localized,] local government can have good control over the health impacts,” he adds. “If they set the [precautionary principle inherent in the] boundary framework, then the cement industry can adapt,” curbing health effects.
Sewage pipes laid in Belgium. Finland-based company Betolar uses industrial waste to replace carbon intensive materials in concrete. According to the company, this solution resulted in a 78% reduction in CO emissions compared to traditional concrete. Image courtesy of StudioFossiel.
The Imagina cultural centerin León, Mexico, is a modern building constructed not of concrete, but of local natural materials: clay adobe, wood and brick, with all 3,500 square meters (about 37,700 square feet) meant as a bold demonstration of bio-construction principles, says bio-architect Peter Van Lengen. The surrounding low-income community was deeply involved in construction, with laborers tutored in adobe techniques, training them for future sustainable building industry jobs. Image courtesy of Peter Van Lengen.
Cleaning up cement and concrete
The industry has principally pulled on three levers so far to begin addressing its carbon emissions, says Ian Riley, CEO of the Global Cement and Concrete Association (GCCA) — improving energy efficiency, swapping out coal and other fossil fuels for “less carbon intensive fuels,” and reducing the proportion of cement clinker (a major CO source).
Other analysts emphasize a current “boom” in research and innovation to clean up cement, including the exploration of solutions that follow a circular economy model.
First off, replacing fossil fuels in the cement making process with alternative fuels could greatly reduce the industry’s carbon footprint. But while projects to electrify cement kilns are underway they’re unlikely to come online at scale for more than a decade, according to a GCCA net-zero roadmap.
Another promising solution focuses on making “low-carbon concrete.” Limestone calcined clay cement, for example, offers a 40% CO reduction over traditional Portland cement and is being considered where calcined clay is available.
Utilizing waste materials as fuel or as aggregate ingredients — including fly ash left over from coal production, and blast furnace slag from steel production — could also reduce emissions, as could agricultural waste, say experts. Researchers are also exploring more radical solutions, such as the use of algae to replace quarried limestone.
All of these ideas are at varying stages of development and deployment, though some may never fully reach the scale required to fulfill future concrete demand, says Riley. “Even today, nobody has a solution to avoid the emissions [generated by clinker production],” he notes. Riley and others suggest carbon capture and storage, or utilizing waste CO within the production process, could one day offer a clinker carbon solution.
A quarry in Nevada, USA. An industry focus on achieving net-zero emissions is crucial for combating climate change, but can “overshadow other significant environmental issues,” connected to concrete production and construction activities, says Nelson Guillermo Rangel-Buitrago, a researcher at Colombia’s Universidad del Atlántico. Image by Bureau of Land Management via Flickr (CC BY 2.0).
Demolition waste. It’s estimated that around 75% of construction and demolition waste is not reused or recycled. Waste that is reused is often “downcycled,” (resulting in a product with lower value than the original item). Experts say that finding ways to reutilize construction waste could release pressure on demand for primary materials and construction aggregates. Image by Dinh Koi Nguyen via Pixabay (Public domain).
Sucking up the carbon produced during the cement making process and then storing it in newly made concrete is envisaged as the ideal solution. Some companies are already applying this method. U.S.-based CarbonCure, for instance, injects captured CO into concrete where it mineralizes and becomes trapped. “Zero carbon cement and concrete will absolutely require CO utilization technologies like ours,” says company CEO Robert Niven, though he adds that this is just one part of a package of solutions needed, which includes such innovations as ramping up the use of recycled concrete aggregate.
Carbon capture has great potential to reduce cement’s footprint, according to Alastair Marsh, a research fellow in alkali-activated materials at the University of Leeds, but he adds that the “proof is in the pudding in terms of how quickly, effectively and at what cost [the technology] can be scaled up.”
Other experts warn that the cost and energy required to install next generation cement technology, particularly in developing countries where demand will be highest, may be out of reach for many economies.
“The hope is that the technology [including carbon capture and electrification] will remove all emissions from cement production. However, that technology sounds good and sounds optimistic, but we don’t have it yet,” says Muhammad Ali, with the Institute for Manufacturing at the University of Cambridge. However, he adds, “There are solutions that can be implemented almost straight away, alongside the development of technology.”
Given that the majority of future carbon emissions from cement and concrete are expected to come from developing countries, Gabo expresses the urgent need for developed nations to invest in solutions which rapidly cut their own emissions, while also supporting developing countries with capacity building and technological advancements.
“We need to have those alternatives cements and other technologies spill over as quickly as possible to the Global South,” Gabo says, so that living standards can improve there, while keeping the emission curve flat.
Reducing carbon emissions from cement production “is going to be one of the hardest nuts to crack,” says Nathan Schroeder, a mechanical engineer with Sandia National Laboratories. He is part of a team trialing the use of concentrated solar to replace fossil fuels as energy for cement production. Image by Sergio Cerrato via Pixabay (Public domain).
Companies such as U.S.-based CarbonCure are injecting captured CO2 into concrete to reduce carbon emissions. The firm says it is nearing a milestone of utilizing 400,000 tons of CO in concrete production, equivalent to the annual emissions of 88,000 cars. Questions of feasibility, cost and scalability remain about carbon capture and storage for cement and concrete production at the global level. Image courtesy of CarbonCure.
“Low-hanging fruit”
In a study published last year, researchers at the University of California Davis found that a combination of improving production methods, using alternative cements, increasing resource efficiency, improving structural design, and increasing the service life of already constructed buildings could significantly slash emissions and other impacts.
Making infrastructure last longer and thereby “Reducing the demand for cement can play a significant role in environmental impact mitigation,” says Josefine Olsson, lead author on the paper and a PhD student in the university’s Department of Civil and Environmental Engineering. “However, we can use concrete more efficiently as well while still meeting the societal needs and continue urban development, especially in developing regions.”
Experts describe such actions, along with the expanded use of traditional building practices — using adobe and other natural bio-based materials as advocated by bio-architects, thereby limiting concrete demand — as “low-hanging fruit” that could be pursued now, without waiting and betting on future technological advances.
Rethinking building design is among the most promising circular solutions, Duwyn agrees. “There is no one-size-fits-all pathway,” he adds. “It’s really about bringing the diversity of solutions together to avoid using too many resources by embracing circularity approaches, enhancing building design, and looking at how we can use more regenerative bio-based materials. By doing so, we can diminish pressure on our world’s resources and reduce environmental impacts effectively.”
Circular economy approaches have their limitations but are an important route to reducing raw materials and energy use, says zu Ermgassen. But in his view, if humanity is to build within the safe limits of planetary boundaries we’ll need to “head towards a steady state infrastructure stock.”
“At some point, there is a fundamental clash between how much our planetary system can tolerate, how much modification and use of resources and energy it can tolerate, and how much infrastructure society will demand,” he says.
Alternatives to cement and concrete are badly needed. Experts say the environmental footprint of these ubiquitous building materials can be reduced via circular economy solutions such as utilizing waste and side streams from industry and the agricultural sector during production of concrete to reduce the amount of cement required. Designing building materials for reuse is another key component of change. Image by Ed Suominen via Flickr (CC BY-NC 2.0).
Banner image: Workers loading cement in 2014 in the Philippines. Cement and concrete production air pollution can impact industry workers and nearby communities. Francis Elehinafe, a professor of chemical engineering at Convenant University in Nigeria, notes that while cement and concrete are the “backbone of industrialization,” tackling their pollution requires a concerted and holistic effort from both governments and industry players. Image by Adam Cohn via Flickr (CC BY-NC-ND 2.0).
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This article was originally published on Mongabay
