Decarbonizing the cementitious materials cycle: A whole‐systems review of measures to decarbonize the cement supply chain in the UK and European contexts

Pamenter, Sarah; Myers, Rupert J.

doi:10.1111/jiec.13105

Cited by 51 publications

(33 citation statements)

References 70 publications

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“…According to the literature on cement’s carbon footprint, the only approach to produce a carbon-neutral cement is by combining bioenergy, the geological storage of CO 2 , and low-carbon energy. ,− Producing carbon-neutral cement by bioenergy and geological storage of CO 2 strongly depends on the location and origin of the bioenergy . In this work, we propose a novel approach that exclusively uses CO 2 mineralization not only to reduce the carbon footprint of cement but also to produce carbon-neutral or even carbon-negative cement requiring neither bioenergy nor geological storage of CO 2 .…”

Section: Discussionmentioning

confidence: 99%

From Unavoidable CO₂ Source to CO₂ Sink? A Cement Industry Based on CO₂ Mineralization

Ostovari

Müller

Skoček

et al. 2021

Environ. Sci. Technol.

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The cement industry emits 7% of the global anthropogenic greenhouse gas (GHG) emissions. Reducing the GHG emissions of the cement industry is challenging since cement production stoichiometrically generates CO 2 during calcination of limestone. In this work, we propose a pathway towards a carbonneutral cement industry using CO 2 mineralization. CO 2 mineralization converts CO 2 into a thermodynamically stable solid and byproducts that can potentially substitute cement. Hence, CO 2 mineralization could reduce the carbon footprint of the cement industry via two mechanisms: (1) capturing and storing CO 2 from the flue gas of the cement plant, and (2) reducing clinker usage by substituting cement. However, CO 2 mineralization also generates GHG emissions due to the energy required for overcoming the slow reaction kinetics. We, therefore, analyze the carbon footprint of the combined CO 2 mineralization and cement production based on life cycle assessment. Our results show that combined CO 2 mineralization and cement production using today's energy mix could reduce the carbon footprint of the cement industry by 44% or even up to 85% considering the theoretical potential. Lowcarbon energy or higher blending of mineralization products in cement could enable production of carbon-neutral blended cement. With direct air capture, the blended cement could even become carbon-negative. Thus, our results suggest that developing processes and products for combined CO 2 mineralization and cement production could transform the cement industry from an unavoidable CO 2 source to a CO 2 sink.

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Section: Discussionmentioning

confidence: 99%

From Unavoidable CO₂ Source to CO₂ Sink? A Cement Industry Based on CO₂ Mineralization

Ostovari

Müller

Skoček

et al. 2021

Environ. Sci. Technol.

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show abstract

“…As construction becomes increasingly important in the lowest emission scenarios, these more extensive measures targeting reduced oor area could make zero emissions targets more attainable. Otherwise, the elimination of embodied emissions will rely on material e ciency 20 and advances in low-carbon material selection and production 29,30 .…”

Section: Technological and Policy Challenges To Mitigationmentioning

confidence: 99%

Decarbonization pathways for the residential sector in the United States

Berrill

Wilson

Reyna

et al. 2022

Preprint

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Residential GHG emissions in the United States are driven in part by a housing stock where on-site fossil combustion is common, home sizes are large by international standards, energy efficiency potential is large, and electricity generation in many regions is GHG-intensive. In this analysis we assess decarbonization pathways for the United States residential sector to 2060, through 108 scenarios describing housing stock evolution, new housing characteristics, renovation levels, and clean electricity. The lowest emission scenarios rely on very rapid decarbonization of electricity supply alongside extensive renovations to existing homes—focused on improving thermal envelopes and heat pump electrification of heating. Reducing the size, increasing the multifamily share, and increasing the electrification of new homes provide further emission cuts, and combining all strategies enables emissions reductions of 91% between 2020 and 2050. Construction becomes the main source of emissions in the most ambitious scenarios, motivating increased attention on reducing embodied emissions.

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“…Moving beyond the cement production stage, Pamenter and Myers (2021) present a semi‐quantitative review of measures to achieve net‐zero GHG emissions across the entire cementitious materials (CMs) cycle. The authors assess the various decarbonization levers that exist across the life‐cycle system, including more efficient kilns, renewable fuels, low‐carbon cement blends, and ME strategies, while quantifying the mitigation potentials of the various measures in a systematic manner.…”

Section: The Role Of Me In Decarbonizing Materials Cyclesmentioning

confidence: 99%

Material efficiency for climate change mitigation

Masanet

Heeren

Kagawa

et al. 2021

J of Industrial Ecology

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Decarbonizing the cementitious materials cycle: A whole‐systems review of measures to decarbonize the cement supply chain in the UK and European contexts

Cited by 51 publications

References 70 publications

From Unavoidable CO₂ Source to CO₂ Sink? A Cement Industry Based on CO₂ Mineralization

From Unavoidable CO₂ Source to CO₂ Sink? A Cement Industry Based on CO₂ Mineralization

Decarbonization pathways for the residential sector in the United States

Material efficiency for climate change mitigation

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Decarbonizing the cementitious materials cycle: A whole‐systems review of measures to decarbonize the cement supply chain in the UK and European contexts

Cited by 51 publications

References 70 publications

From Unavoidable CO2 Source to CO2 Sink? A Cement Industry Based on CO2 Mineralization

From Unavoidable CO2 Source to CO2 Sink? A Cement Industry Based on CO2 Mineralization

Decarbonization pathways for the residential sector in the United States

Material efficiency for climate change mitigation

Contact Info

Product

Resources

About

From Unavoidable CO₂ Source to CO₂ Sink? A Cement Industry Based on CO₂ Mineralization

From Unavoidable CO₂ Source to CO₂ Sink? A Cement Industry Based on CO₂ Mineralization