Featured Post

PROFILE : My journey to Professional Registration - Innocent Gininda

Innocent Gininda shares his journey to becoming a registered Professional Engineer (PrEng), emphasizing the importance of mentorship, early preparation, and understanding ECSA requirements. He offers advice to aspiring PrEngs, highlighting the value of diverse feedback and a positive mindset. My journey to becoming a registered Professional Engineer (PrEng) culminated successfully in November 2024. I was fortunate to begin my career at a company with a Commitment and Undertaking (C&U) Agreement with ECSA and a robust mentorship program. This commitment to training engineers to the standard required for Professional Registration provided me with essential resources and a structured path to track my experience against ECSA requirements. Early exposure to these expectations instilled a positive outlook on registration and solidified my desire to achieve this milestone. My views on Professional Registration have remained consistently positive throughout this journey. Working alongside ...

NEWS: CO2 can help the construction industry emit less CO2. Here's how

 The construction sector's productivity and CO2 footprint are key problems that need to be addressed quickly to meet the increasing demand for construction while reducing the damage to the environment.


A key to solving both the construction sector productivity and CO2 footprint problems may very well lie within the CO2 itself.

Limitations in productivity could be addressed with the rapid and large-scale introduction of automation into the industry. Traditionally, automation has propelled productivity upwards in many industries but that is usually coupled with job losses. This will be different in a construction industry that today faces a global shortage in available labour. The introduction of automation tools enables 3D-printing of concrete materials, better prefabrication of building modules, and can help assembling entire structures. Overall, this enables new building designs, with lower cost, and reduces the physical burden on construction workers, all while adding new jobs to implement and operate the tools.

While 3D printing of concrete has been pursued for some time it will benefit from advances in concrete materials to enable better printability, such as increased speed of construction while preserving structural integrity. In addition, advanced concretes must have properties such as higher mechanical stability, smart thermal behaviour, air filtration and self-repair capability. But first and foremost, in the present context, these materials need to offer better manufacturability and a better carbon footprint.

New materials will become critical enablers for advances in construction. An opportunity exists to focus research and developments on concrete and concrete-like composite materials that incorporate captured CO2 as an ingredient. This CO2 could be taken directly from the air, but it can also be harvested from powerplants or cement factories. In either case, the CO2 will be permanently removed in a mineralized form and therefore such efforts will help to address climate change effects.

CO2 can become an enabling raw material for the construction industry and beyond in multiple ways. First, it is possible to use CO2 in the curing of cement in a way for which water is traditionally used. Emerging commercial demonstrations are noted for premade modules as well as concrete that is poured at construction sites. Second, industrial waste materials, such as steel slag, fly ash from power plants or mine tailings can be reacted with CO2 to form carbonate materials that are suitable ingredients for concrete. Third, plant fibres and plant-derived polymers can be developed into components for concrete.

Concrete is a versatile material for which many properties will continue to evolve to meet particular use cases. Engineered cementitious composites (ECC) are a class of concrete materials that combine the strength of concrete with the ductility of metals. This is in part achieved through the introduction of polymer fibres into the concrete mixture. Like other concretes, ECC can include CO2 as described above and could offer additional opportunities for carbon sequestration via the use of plant fibres instead of polymer fibers.

Substantial barriers exist in the way bringing CO2-based composites for competitive construction methods to full-scale deployment. Work that is needed includes design and testing of new materials, as well as reworking and expanding the supply chain. It includes the creation of appropriate demand for these materials in a traditionally risk-averse environment, and thus requires suitable policy support.

Also read: How can the construction industry reduce noise levels to manage its carbon footprint?

Lessons learned from the Fourth Industrial Revolution can help the construction industry, too. The environmental, economic and – in turn – societal benefits are worth the effort. In total, CO2-based construction materials offer an opportunity for the removal of gigatons of CO2. This category of captured carbon products is the only one that offers permanent removal opportunities in contrast to other CO2 utilization cases. These will still be crucially important for an overall carbon neutral planet since they allow the production of carbon containing materials such as fuels, chemical, and polymers without adding more carbon into the system.


If you would like to receive email alerts when Hardhat Career Tips articles are published submit your details here

If you only like to receive Hardhat Career Tips images submit your details here

Comments