Representation of Balancing Options for Variable Renewables in Long-Term Energy System Models: An Application to OSeMOSYS

Gardumi, Francesco; Welsch, Manuel; Howells, Mark; Colombo, Emanuela

doi:10.3390/en12122366

Cited by 20 publications

(13 citation statements)

References 20 publications

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“…In short, OSeMOSYS prioritises the least-cost pathway formed from technologies to determine a country or region's future energy mix (Howells et al, 2011). An optimal least-cost approach is useful for operational analysis of variable and xed costs of both short-term upfront capital costs and longterm investment plans (Gardumi et al, 2019). Due to the model's open-source nature, the input data is ideally free and publicly available.…”

Section: Methodsmentioning

confidence: 99%

Long-term Energy System Modelling for a Clean Energy Transition in Egypt's Energy Sector

Gibson

2023

Preprint

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Egypt has the potential to generate significant amounts of renewable energy, particularly solar PV, concentrated solar power (CSP) and onshore and offshore wind. Its large economy and rapidly growing population mean that the country is facing increasing energy demand. The energy sector is reliant on fossil fuels, particularly natural gas, for electricity production and is at risk of locking itself into a high carbon pathway. Globally, reducing greenhouse gas (GHG) emissions associated with national energy sectors is a target outlined in the UN’s Paris Agreement. To reduce carbon dioxide (CO2) emissions associated with a higher dependence on fossil fuels, Egypt must consider upscaling renewable energy technologies (RET) to achieve a clean energy transition (CET). This research modelled six scenarios using OSeMOSYS to identify the technologies and policy target improvements that are needed to upscale RETs within the energy sector. OSeMOSYS is a bottom-up, long-term energy system model that applies linear optimisation techniques to determine an array of least-cost technologies to satisfy a defined energy demand. The results showed that solar PV and onshore wind are key technologies to be upscaled to contribute towards Egypt’s CET. The optimal renewable target is the International Renewable Energy Agency’s (IRENA) 53% of electricity to be sourced from RETs by 2030, which will cost $16.4 billion more up to 2035 than Egypt’s current Integrated Sustainable Energy Strategy (ISES) target of 42% by 2035; it also saves 732.0 Mt of CO2 over the entire modelling period to 2070. Socio-economic barriers to this transition are considered, such as recent discoveries of natural gas reserves combined with a history of energy insecurity, political instability impacting investor confidence, and a lack of international climate funding. The paper concludes with policy recommendations that will enable Egypt to achieve a CET.

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Section: Methodsmentioning

confidence: 99%

Long-term Energy System Modelling for a Clean Energy Transition in Egypt's Energy Sector

Gibson

2023

Preprint

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“…The objective function to be minimized is the net present cost of the energy system to meet the given energy and energy service demands over the simulation period. In other words, it is the sum over all regions (r) and years (y) of the discounted costs of all technologies (t) and storage systems (s) [40]:…”

Section: Modelling Frameworkmentioning

confidence: 99%

“…The framework makes use of three technology cost parameters: CapitalCostr,t,y (CC), that is, the capital investment cost of a technology per unit of capacity; VariableCostr,t,m,y (VC), that The objective function to be minimized is the net present cost of the energy system to meet the given energy and energy service demands over the simulation period. In other words, it is the sum over all regions (r) and years (y) of the discounted costs of all technologies (t) and storage systems (s) [40]:…”

Section: Modelling Frameworkmentioning

confidence: 99%

Supporting Decarbonization Strategies of Local Energy Systems by De-Risking Investments in Renewables: A Case Study on Pantelleria Island

et al. 2022

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Nowadays, energy policymakers are asked to develop strategies to ensure an affordable clean energy supply as well as minimizing investment risks. In addition, the rise of several community engagement schemes and the uptake of user-scale technologies introduce uncertainties that may result in a disruptive factor for energy systems evolution. This paper introduces a novel scenario analysis approach for local energy planning that supports policymakers and investors in prioritizing new renewable power plant investments, addressing the risks deriving from citizens’ choices. Specifically, a combined analysis is performed on the adoption trends of distributed photovoltaic systems and electric vehicles that are expected to heavily influence the evolution of energy systems. For this reason, an energy model is developed for Pantelleria island, and its transition from an oil-based energy supply to a renewable one up to 2050 is investigated. It is demonstrated how optimal-cost renewable-based scenarios can assure a 45% to 52% CO2 emissions reduction and a 6% to 15% overall cost reduction with respect to the diesel-based business-as-usual scenario. The analyzed scenarios disclose the recommended investments in each renewable technology, considering their learning curves and the unpredictability of user-scale technology adoption. Consequently, priorities in the installation of renewable power plants are stressed, starting with the most resilient to future uncertainties, as well as promoting specific incentive measures for citizens’ commitment at a local scale.

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“…It has had several applications. Recently, it has been used to study options for stabilizing renewable energy sources in long-term energy systems (Gardumi et al 2019), modeling energy systems to evaluate alternative scenarios (Quevedo and Moya 2022), and modeling solutions for energy security in the electricity sector (Yeganyan 2021) among others.…”

Section: The Osemosys Modelmentioning

confidence: 99%

Modelling the electricity mix for Togo by 2050 using OSeMOSYS

Tchandao

2022

Preprint

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This work uses bottom-up modeling to explore the future evolution trajectories of the electricity mix in Togo by 2050. The objective is to investigate the evolution of the mix and the future investments needed to achieve the sustainable energy and climate change goals. Three scenarios were developed using OSeMOSYS. The reference scenario, named Business As Usual, closely reflects the evolution of the Togolese electricity sector under a business-as-usual assumption and planned capacity increases up to 2030. The second scenario, Net Zero by 2050, is based on the first scenario while ensuring that CO2 emissions cancel out in 2050 by following the Weibull law. The third scenario called Emission Penalty aims not only at the integration of renewable energies like the second one but also at the least cost electricity mix if emission penalties are applied. The results of the cost optimization indicate that photovoltaic and importation are the optimal choices ahead of gas and hydropower. The renewable energy aspect of the electricity mix is more highlighted in the last scenario. At the same time, the model shows that greater energy independence is achievable at the cost of a transitory increase in the cost of the electricity system. A tenfold investment effort is needed in 2030 to ensure either continuity of the status quo or a shift in strategy.

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Representation of Balancing Options for Variable Renewables in Long-Term Energy System Models: An Application to OSeMOSYS

Cited by 20 publications

References 20 publications

Long-term Energy System Modelling for a Clean Energy Transition in Egypt's Energy Sector

Long-term Energy System Modelling for a Clean Energy Transition in Egypt's Energy Sector

Supporting Decarbonization Strategies of Local Energy Systems by De-Risking Investments in Renewables: A Case Study on Pantelleria Island

Modelling the electricity mix for Togo by 2050 using OSeMOSYS

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