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How It Works

Select your project area, concrete mix class, and the type of Supplementary Cementitious Material (SCM) with the replacement percentage. Click Calculate to see the estimated CO₂ emissions and potential reductions.
Note – This tool uses a standardized formula and assumes a 5% margin to minimize miscalculations and improve on-site efficiency.

Area

Concrete Strength Mix Class

Supplementary Cementitious Material Type (SCM)

Replacement Percentage

Note: All fields mandatory.
Calculate

CO₂ Emission (Kg/m³)

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CO₂ Reduction (Kg/m³)

0

CO₂ Reduction (%)

0%

Estimated Service Life (years)

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What’s your project’s carbon footprint?

Use our Carbon Calculator to estimate the CO₂ emissions associated with your concrete mix design. The tool helps project planners and sustainability managers evaluate emissions, identify reduction opportunities, and select lower-impact materials. Whether you’re working on infrastructure or industrial sites, this calculator supports data-driven environmental decisions.

Key Sustainability Metrics

Precise Emission Estimates

Accurately calculates CO₂ emissions per cubic meter (Kg/m³)

Smart Optimization Suggestions

Provides reduction potential using SCMs and optimized concrete mixes

Trusted Environmental Insights

Backed by industry expertise and aligned with sustainability standards

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Need Technical Support?

Our team is here to assist you with any questions related to specifications, volume calculations, or product suitability.

Reach out today and get expert advice fit to your project’s needs.

Contact Us

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Know about Carbon

Understand the different sources of carbon emissions in construction, their impact on the environment, and the best ways to manage or reduce them — from material selection to production methods. Choosing the right materials and processes helps ensure sustainability, compliance, and cost-efficiency.

Carbon intensity measures the amount of carbon dioxide (CO₂) emitted per unit of product or process. High carbon intensity contributes to climate change and may attract higher carbon taxes or penalties. Reducing it is essential for environmentally responsible construction and meeting ESG goals.

Carbon footprint influences decisions on which materials to use. For example, low-carbon cement or concrete mixes with Ground Granulated Blast Furnace Slag (GGBFS) significantly reduce emissions. Material selection directly impacts sustainability ratings such as LEED or Envision.

Materials with high moisture content require more energy to process and transport, increasing their embodied carbon. Proper storage and handling can minimize unnecessary carbon output and contribute to overall emission reduction.

Clinker is one of the most carbon-intensive components in cement. Substituting it with slag or other supplementary cementitious materials can cut CO₂ emissions by up to 40%. Understanding this trade-off helps optimize both performance and sustainability.

Long-distance transportation and improper storage lead to higher fuel use and product waste. Efficient logistics planning and local sourcing are key strategies for reducing the carbon impact associated with construction material movement.

Global and regional standards such as ISO 14067, EN 15804, and Saudi Green Building Code guide carbon reporting and material assessment. Compliance ensures credibility and supports decarbonization strategies across the supply chain.