Energy Transition Pathways for Deep Decarbonization of the Greater Montreal Region: An Energy Optimization Framework

Sani, Sajad Aliakbari; Maroufmashat, Azadeh; Babonneau, Frédéric Louis François; Bahn, Olivier; Delage, Erick; Haurie, Alain; Mousseau, Normand; Vaillancourt, Kathleen

doi:10.3390/en15103760

Cited by 3 publications

(1 citation statement)

References 29 publications

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“…However, these measures should be weighed against energy security. This issue takes the main role in formulating plans in view of the current geopolitical challenges and situations in the world [40][41][42][43][44].…”

Section: The Electricity Generation Sectormentioning

confidence: 99%

Optimization Modelling of the Decarbonization Scenario of the Total Energy System of Kazakhstan until 2060

et al. 2023

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This research article provides a comprehensive scenario analysis of key structural changes in Kazakhstan’s fuel and energy complex subsectors until 2060, focusing on decarbonization efforts. The background places the issue of decarbonization in a broader context, considering the country’s vast size and sparse population. The study’s purpose involves analyzing the development of the climate agenda by comparing two scenarios: a “reference” scenario without decarbonization measures and a carbon neutrality scenario until 2060 (CN2060). A mathematical technical-economic model based on the TIMES paradigm (The Integrated MARKAL-EFOM System) serves as the method to optimize and simulate Kazakhstan’s energy system. The main findings reveal sets of policies, standards, and legislative, economic, and political decisions that are required to achieve CN2060. Additionally, the integration of a low-carbon policy, sectoral and cross-cutting approaches, the impact of the coronavirus crisis, the Russia-Ukraine conflict, and energy security issues receive a discussion. The article concludes with projected shares of generation and investment in renewable energy sources (RES) necessary for attaining CN2060. This work offers novel insights into challenges and opportunities for Kazakhstan’s transition to a low-carbon economy.

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Section: The Electricity Generation Sectormentioning

confidence: 99%

Optimization Modelling of the Decarbonization Scenario of the Total Energy System of Kazakhstan until 2060

et al. 2023

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Assessing electric mobility and renewable energy synergy in a small New Caledonia Island community

Babonneau

Chotard

Haurie

2023

International Journal of Green Energy

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Optimizing Renewable Injection in Integrated Natural Gas Pipeline Networks Using a Multi-Period Programming Approach

et al. 2023

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In this paper, we propose an optimization model that considers two pathways for injecting renewable content into natural gas pipeline networks. The pathways include (1) power-to-hydrogen or PtH, where off-peak electricity is converted to hydrogen via electrolysis, and (2) power-to-methane, or PtM, where carbon dioxide from different source locations is converted into renewable methane (also known as synthetic natural gas, SNG). The above pathways result in green hydrogen and methane, which can be injected into an existing natural gas pipeline network. Based on these pathways, a multi-period network optimization model that integrates the design and operation of hydrogen from PtH and renewable methane is proposed. The multi-period model is a mixed-integer non-linear programming (MINLP) model that determines (1) the optimal concentration of hydrogen and carbon dioxide in the natural gas pipelines, (2) the optimal location of PtH and carbon dioxide units, while minimizing the overall system cost. We show, using a case study in Ontario, the optimal network structure for injecting renewable hydrogen and methane within an integrated natural gas network system provides a $12M cost reduction. The optimal concentration of hydrogen ranges from 0.2 vol % to a maximum limit of 15.1 vol % across the network, while reaching a 2.5 vol % at the distribution point. This is well below the maximum limit of 5 vol % specification. Furthermore, the optimizer realized a CO2 concentration ranging from 0.2 vol % to 0.7 vol %. This is well below the target of 1% specified in the model. The study is essential to understanding the practical implication of hydrogen penetration in natural gas systems in terms of constraints on hydrogen concentration and network system costs.

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Energy Transition Pathways for Deep Decarbonization of the Greater Montreal Region: An Energy Optimization Framework

Cited by 3 publications

References 29 publications

Optimization Modelling of the Decarbonization Scenario of the Total Energy System of Kazakhstan until 2060

Optimization Modelling of the Decarbonization Scenario of the Total Energy System of Kazakhstan until 2060

Assessing electric mobility and renewable energy synergy in a small New Caledonia Island community

Optimizing Renewable Injection in Integrated Natural Gas Pipeline Networks Using a Multi-Period Programming Approach

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