Martin Colla scite author profile

The decarbonisation of the electricity sector can be a key contributor in the transition to sustainable energy systems. New low-carbon power production technologies are becoming available in the international market, contributing to building diversified portfolios of projects with very different features. Apart from technology-related features, the deployment of a power generation plant also depends on the availability of resources of the country/installation site, socioeconomic implications, environmental impact and integration with the existing power grid. Decision makers should take all these factors into consideration when determining which project is more likely to move forward. Several studies have proposed the use of Key Performance Indicators (KPIs) to facilitate the decision-making process when selecting viable and sustainable energy projects. However, fewer studies exist that provide a detailed assessment of these KPIs. The scope of this paper is to critically review and investigate a set of multidisciplinary KPIs, allowing a holistic comparison across different types of energy projects. The identified KPIs were classified as physical, economic, environmental and social. They were then analysed to assess their limitations, determine inter-connections and identify the need for additional indicators to capture risks and opportunities within a mixed energy market. This paper can be the basis for the development of an integrated framework, allowing a fairer assessment of competing energy projects by relevant stakeholders.

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Optimal Use of Lignocellulosic Biomass for the Energy Transition, Including the Non-Energy Demand: The Case of the Belgian Energy System

Colla

Blondeau

Jeanmart

2022

Front. Energy Res.

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Biomass is a key renewable resource for energy transition and climate change mitigation. It can be used for either energy purposes (production of heat, electricity, and fuel) or non-energy demand (e.g., chemicals). This raises the question of the optimal use of biomass in energy systems. In the literature, this optimal use is often determined for one specific situation in terms of greenhouse gas emissions and rarely considering the non-energy demand. The non-energy demand is defined as the demand for energy products used as raw materials. Given the expected simultaneous changes in all industrial sectors, it is important to include the non-energy demand in the models of energy systems as they will share common resources. This paper 1) studies the optimal use of lignocellulosic biomass within an energy system including the non-energy demand and 2) analyzes the evolution of its role throughout the energy transition. Belgium is taken as a case study as it presents a non-energy demand corresponding to ∼15% of its primary energy mix. The energy system is modeled with EnergyScope TD which optimizes whole-energy systems in terms of costs under greenhouse gas emission constraints. Local and imported biomass is considered with two potential scenarios. Fourteen biomass-converting technologies are included in the model. It is shown that high-temperature heat remains a significant application for biomass in all scenarios and increases when moving toward carbon neutrality. For greenhouse gas savings below 50%, biomass is largely used for low-temperature heat. However, when aiming at reducing greenhouse gas further (>50% reduction), biomass is substantially exploited for the non-energy demand. Electricity from biomass also appears, to a lesser extent, for large greenhouse gas savings only. The integration of the non-energy demand in the simulations impacts the allocation of biomass in the system, depending on the scenario of potential considered.

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Integration of non-energy among the end-use demands of bottom-up whole-energy system models

et al. 2022

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The complexity of bottom-up energy system models has progressively grown to enhance the representativeness of the system under analysis. Among them, whole-energy system models aim at representing the energy resources, conversion technologies, and energy demands of regions (i.e., a country) in its entirety. Despite this effort leading to an increased number of conversion processes modeled, the typologies of the end-use demand have remained limited to three categories: electricity, heat, and transportation. A fourth category, herein addressed as the non-energy demand, has widely been neglected. Being associated with the production of chemicals (i.e., plastics and fertilizers), the non-energy demand represents 10% of the world’s total end-use demand. Its relevance becomes fundamental in analyses that define the optimal defossilization pathways of energy systems with high dependence on fossil resources. This contribution introduces a schematic representation of the conversion processes involved in the satisfaction of the non-energy demand. Through its implementation in a bottom-up whole-energy system model, it evaluates the impact of this additional end-use in the configuration of the optimal energy system. In this study, the Belgian energy system, characterized by a penetration of the chemical and the petrochemical industries up to 20% of its total end-use demand, is taken as a reference case. The transition to a defossilized energy system is enforced through a snapshot analysis with a progressively more restrictive emissions cap. The results emphasize the role of renewable carriers (i.e., methanol and ammonia) in the defossilization of the energy system, otherwise hindered when the non-energy demand is neglected. The 100% import of these carriers at the lowest emissions cap highlights the potential dependence of the country under analysis, with limited availability of renewable resources, from countries exporting renewable methanol and ammonia.

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Martin Colla

Critical review of competitiveness indicators for energy projects

Optimal Use of Lignocellulosic Biomass for the Energy Transition, Including the Non-Energy Demand: The Case of the Belgian Energy System

Integration of non-energy among the end-use demands of bottom-up whole-energy system models

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