Assessing flexibility for integrating renewable energies into carbon neutral multi-regional systems: The case of the Chilean power system
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[1] P. Laha,et al. Cost optimal combinations of storage technologies for maximizing renewable integration in Indian power system by 2040: Multi-region approach , 2021 .
[2] W. Purwanto,et al. Pathway towards 100% renewable energy in Indonesia power system by 2050 , 2021 .
[3] D. Rasella,et al. Health and environmental impacts of replacing kerosene-based lighting with renewable electricity in East Africa , 2021 .
[4] Smail Zouggar,et al. Electric System Cascade Extended Analysis for optimal sizing of an autonomous hybrid CSP/PV/wind system with Battery Energy Storage System and thermal energy storage , 2021, Energy.
[5] Petra Valíčková,et al. Potential gains from regional integration to reduce costs of electricity supply and access in Southern Africa , 2021 .
[6] Diyi Chen,et al. Flexibility assessment of a hybrid power system: Hydroelectric units in balancing the injection of wind power , 2021 .
[7] M. Adaramola,et al. Socio-economic and environmental impacts of rural electrification with Solar Photovoltaic systems: Evidence from southern Ethiopia , 2021 .
[8] R. Escobar,et al. Identifying optimum CSP plant configurations for spot markets using a dispatch optimization algorithm – A case study for Chile , 2020 .
[9] Iddrisu Awudu,et al. Renewable electricity generation target setting in developing countries: Modeling, policy, and analysis , 2020 .
[10] María Mercedes Vanegas Cantarero. Of renewable energy, energy democracy, and sustainable development: A roadmap to accelerate the energy transition in developing countries , 2020 .
[11] Armando L. Figueroa-Acevedo,et al. Challenges of planning for high renewable futures: Experience in the U.S. midcontinent electricity market , 2020 .
[12] Gopika G. Jayadev,et al. U.S. electricity infrastructure of the future: Generation and transmission pathways through 2050 , 2020 .
[13] William D'haeseleer,et al. Unit commitment constraints in long-term planning models: Relevance, pitfalls and the role of assumptions on flexibility , 2020 .
[14] Andrew Rowe,et al. Flexibility requirements and electricity system planning: Assessing inter-regional coordination with large penetrations of variable renewable supplies , 2020 .
[15] Emanuela Colombo,et al. Representation of Balancing Options for Variable Renewables in Long-Term Energy System Models: An Application to OSeMOSYS , 2019, Energies.
[16] Matias Negrete-Pincetic,et al. The impact of concentrated solar power in electric power systems: A Chilean case study , 2019, Applied Energy.
[17] Nikolaos E. Koltsaklis,et al. State-of-the-art generation expansion planning: A review , 2018, Applied Energy.
[18] Rodrigo Escobar,et al. Techno-economic evaluation of a hybrid CSP + PV plant integrated with thermal energy storage and a large-scale battery energy storage system for base generation , 2018, Solar Energy.
[19] Ning Zhang,et al. Economic justification of concentrating solar power in high renewable energy penetrated power systems , 2018, Applied Energy.
[20] Rodrigo Palma-Behnke,et al. Sunset or sunrise? Understanding the barriers and options for the massive deployment of solar technologies in Chile , 2018 .
[21] Claudio Vergara,et al. Renewable energy curtailment: A case study on today's and tomorrow's congestion management , 2018 .
[22] Adam Hawkes,et al. The future cost of electrical energy storage based on experience rates , 2017, Nature Energy.
[23] Alexandre Szklo,et al. Assessing the potential role of concentrated solar power (CSP) for the northeast power system of Brazil using a detailed power system model , 2017 .
[24] Michael Milligan,et al. Hydro power flexibility for power systems with variable renewable energy sources: an IEA Task 25 collaboration , 2017 .
[25] Alexandre Szklo,et al. Modelling concentrated solar power (CSP) in the Brazilian energy system: A soft-linked model coupling approach , 2016 .
[26] Rodrigo Escobar,et al. Assessing the performance of hybrid CSP + PV plants in northern Chile , 2016 .
[27] Irene Schiattino,et al. Impact of large industrial emission sources on mortality and morbidity in Chile: A small-areas study. , 2016, Environment international.
[28] Constantinos Taliotis,et al. An indicative analysis of investment opportunities in the African electricity supply sector — Using TEMBA (The Electricity Model Base for Africa) , 2016 .
[29] Bryan Palmintier,et al. Impact of operational flexibility on electricity generation planning with renewable and carbon targets , 2016, 2016 IEEE Power and Energy Society General Meeting (PESGM).
[30] Goran Strbac,et al. Supporting security and adequacy in future energy systems: The need to enhance long‐term energy system models to better treat issues related to variability , 2015 .
[31] David Kleinhans,et al. Integration of Renewable Energy Sources in future power systems: The role of storage , 2014, 1405.2857.
[32] Daniel M. Kammen,et al. The role of large-scale energy storage design and dispatch in the power grid: A study of very high grid penetration of variable renewable resources , 2014 .
[33] Adam Hawkes,et al. Energy systems modeling for twenty-first century energy challenges , 2014 .
[34] Semida Silveira,et al. OSeMOSYS: The Open Source Energy Modeling System: An introduction to its ethos, structure and development , 2011 .