Trends in the global cement industry and opportunities for long-term sustainable CCU potential for Power-to-X

Farfan, Javier; Fasihi, Mahdi; Breyer, Christian

doi:10.1016/j.jclepro.2019.01.226

Cited by 132 publications

(42 citation statements)

References 54 publications

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“…They predicted stabilization in cement consumption by the year 2050, as industries will defer away from manufacturing CO 2 emission intensive products ( Figure 4 b). Farfan et al [ 26 ] examined an alternate view of projected cement consumption, with closing gaps in the world’s GDP growth and infrastructure development needs. An increase in the development of African, Asian, and Latin American countries will result in a peak of global cement production around year 2030, followed by a decrease until year 2050 ( Figure 4 c).…”

Section: Model Backgroundmentioning

confidence: 99%

Mitigating Portland Cement CO2 Emissions Using Alkali-Activated Materials: System Dynamics Model

Nehdi

Yassine

2020

Materials

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While alkali-activated materials (AAMs) have been hailed as a very promising solution to mitigate colossal CO2 emissions from world portland cement production, there is lack of robust models that can demonstrate this claim. This paper pioneers a novel system dynamics model that captures the system complexity of this problem and addresses it in a holistic manner. This paper reports on this object-oriented modeling paradigm to develop a cogent prognostic model for predicting CO2 emissions from cement production. The model accounts for the type of AAM precursor and activator, the service life of concrete structures, carbonation of concrete, AAM market share, and policy implementation period. Using the new model developed in this study, strategies for reducing CO2 emissions from cement production have been identified, and future challenges facing wider AAM implementation have been outlined. The novelty of the model consists in its ability to consider the CO2 emission problem as a system of systems, treating it in a holistic manner, and allowing the user to test diverse policy scenarios, with inherent flexibility and modular architecture. The practical relevance of the model is that it facilitates the decision-making process and policy making regarding the use of AAMs to mitigate CO2 emissions from cement production at low computational cost.

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Section: Model Backgroundmentioning

confidence: 99%

Mitigating Portland Cement CO2 Emissions Using Alkali-Activated Materials: System Dynamics Model

Nehdi

Yassine

2020

Materials

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“…The electricity demand to produce hydrogen and FT‐fuels (diesel, petrol, and kerosene) is derived by applying respective value chains and taking CO 2 direct air capture (DAC) into account to achieve the required level of sustainability. The CO 2 could also originate from a carbon point source, which is either sustainable because of bio‐CO 2 (pulp and paper mills) or unavoidable because of lack of better options (limestone fraction of cement mills or municipal solid waste incinerators). CO 2 DAC is also taken into account in this research because of the limited amount of sustainable and unavoidable carbon point sources .…”

Section: Methodsologymentioning

confidence: 99%

Solar photovoltaic capacity demand for a sustainable transport sector to fulfil the Paris Agreement by 2050

Breyer

Khalili

Bogdanov

2019

Progress in Photovoltaics

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The Paris Agreement sets a clear target for net zero greenhouse gas (GHG) emissions by the mid‐21st century. This implies that the transport sector has to reach zero GHG emissions mainly through direct and indirect electrification in the form of synthetic fuels, such as hydrogen and Fischer‐Tropsch (FT) fuels. The results of this research document that this very ambitious target is possible. This research analyses the global solar photovoltaics (PV) demand for achieving the Paris targets in the transport sector by the year 2050. The methodology is composed of the derivation of the transportation demand converted into final energy demand for direct electrification, hydrogen, methane, and FT‐fuels production. The power‐to‐gas (H2, CH4) and power‐to‐liquids (FT fuels) value chains are applied for the total electricity demand, which will be mostly fulfilled by PV, taking into account previous results concerning the renewable electricity share of the energy transition in the power sector for the world structured in 145 regions and results aggregated to nine major regions. The results show a continuous demand increase for all transportation modes till 2050. The total global PV capacity demand by 2050 for the transport sector is estimated to be about 19.1 TWp, thereof 35%, 25%, 7%, and 33% for direct electrification, hydrogen, synthetic natural gas, and FT fuels, respectively. PV will be the key enabler of a full defossilisation of the transport sector with a demand comparable with the power sector but a slightly later growth dynamic, leading to a combined annual PV capacity demand of about 1.8 TWp around 2050.

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“…However, it is important to have sustainably sourced carbon and hydrogen in order to have zero net-emissions of CO2. CO2 direct air capture [38] or point source CO2 capture technologies, such as for cement mills [54], will be able to provide sustainable or otherwise unavoidable carbon, whereas water electrolysis will allow to create hydrogen by the well-known water electrolysis process. In addition, these energy-intensive PtX technologies convert large amounts of electricity from solar PV and wind turbines into hydrocarbons, while providing a very high flexibility to the entire energy system [19], [52], which also effectively limits curtailment of electricity.…”

Section: A Overall Findingsmentioning

confidence: 99%

The Value of Fast Transitioning to a Fully Sustainable Energy System: The Case of Turkmenistan

2021

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Trends in the global cement industry and opportunities for long-term sustainable CCU potential for Power-to-X

Cited by 132 publications

References 54 publications

Mitigating Portland Cement CO2 Emissions Using Alkali-Activated Materials: System Dynamics Model

Mitigating Portland Cement CO2 Emissions Using Alkali-Activated Materials: System Dynamics Model

Solar photovoltaic capacity demand for a sustainable transport sector to fulfil the Paris Agreement by 2050

The Value of Fast Transitioning to a Fully Sustainable Energy System: The Case of Turkmenistan

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