Integration of high levels of electrolytic hydrogen production: Impact on power systems planning

[1]  Juan Carlos Osorio-Aravena,et al.  Exporting sunshine: Planning South America’s electricity transition with green hydrogen , 2022, Applied Energy.

[2]  Eduardo Álvarez-Miranda,et al.  Assessing flexibility for integrating renewable energies into carbon neutral multi-regional systems: The case of the Chilean power system , 2022, Energy for Sustainable Development.

[3]  K. Khalilpour,et al.  Evaluation of green hydrogen carriers: A multi-criteria decision analysis tool , 2022, Renewable and Sustainable Energy Reviews.

[4]  H. L.,et al.  A long-term capacity investment and operational energy planning model with power-to-X and flexibility technologies , 2022, Renewable and Sustainable Energy Reviews.

[5]  C. Marcantonini,et al.  Value of green hydrogen when curtailed to provide grid balancing services , 2022, International Journal of Hydrogen Energy.

[6]  Carlos A. Cervantes-Ortiz,et al.  Key aspects in quantifying massive solar hydrogen production: Energy intermittence, water availability and electrolyzer technology , 2022, Journal of Cleaner Production.

[7]  J. Yusta,et al.  Optimal dispatch model for PV-electrolysis plants in self-consumption regime to produce green hydrogen: A Spanish case study , 2022, International Journal of Hydrogen Energy.

[8]  M. Brear,et al.  The role of hydrogen in decarbonizing a coupled energy system , 2022, Journal of Cleaner Production.

[9]  Nilay N. Shah,et al.  A framework for the design & operation of a large-scale wind-powered hydrogen electrolyzer hub , 2022, International Journal of Hydrogen Energy.

[10]  P. B. Andersen,et al.  Ancillary services and electric vehicles: An overview from charging clusters and chargers technology perspectives , 2022, Renewable and Sustainable Energy Reviews.

[11]  E. Zoulias,et al.  Hydrogen in Grid Balancing: The European Market Potential for Pressurized Alkaline Electrolyzers , 2022 .

[12]  Oliver Ruhnau How flexible electricity demand stabilizes wind and solar market values: The case of hydrogen electrolyzers , 2021, Applied Energy.

[13]  Juan Carlos Osorio-Aravena,et al.  The impact of renewable energy and sector coupling on the pathway towards a sustainable energy system in Chile , 2021 .

[14]  Matias Negrete-Pincetic,et al.  Optimization-based analysis of decarbonization pathways and flexibility requirements in highly renewable power systems , 2021 .

[15]  N. Lewis,et al.  Opportunities for flexible electricity loads such as hydrogen production from curtailed generation , 2021, Advances in Applied Energy.

[16]  M. Lynch,et al.  Green hydrogen for heating and its impact on the power system , 2021, International Journal of Hydrogen Energy.

[17]  M. G. Dozein,et al.  Fast Frequency Response From Utility-Scale Hydrogen Electrolyzers , 2021, IEEE Transactions on Sustainable Energy.

[18]  Daniel Hissel,et al.  Hydrogen energy systems: A critical review of technologies, applications, trends and challenges , 2021, Renewable and Sustainable Energy Reviews.

[19]  Abbas Rabiee,et al.  Green hydrogen: A new flexibility source for security constrained scheduling of power systems with renewable energies , 2021, International Journal of Hydrogen Energy.

[20]  E. Wetterlund,et al.  Stronger together: Multi-annual variability of hydrogen production supported by wind power in Sweden , 2021, Applied Energy.

[21]  E. Bocci,et al.  A Techno-Economic Analysis of solar hydrogen production by electrolysis in the north of Chile and the case of exportation from Atacama Desert to Japan , 2020, International Journal of Hydrogen Energy.

[22]  Robin Girard,et al.  Quantifying power system flexibility provision , 2020, Applied Energy.

[23]  Omar J. Guerra,et al.  Flexible grid-based electrolysis hydrogen production for fuel cell vehicles reduces costs and greenhouse gas emissions , 2020 .

[24]  Yuan Huang,et al.  Exploring flexibility of electric vehicle aggregators as energy reserve , 2020, Electric Power Systems Research.

[25]  Anthony Velazquez Abad,et al.  Green hydrogen characterisation initiatives: Definitions, standards, guarantees of origin, and challenges , 2020, Energy Policy.

[26]  Tao Lv,et al.  Power system planning with increasing variable renewable energy: A review of optimization models , 2020 .

[27]  Cédric Philibert,et al.  Flexible production of green hydrogen and ammonia from variable solar and wind energy: Case study of Chile and Argentina , 2020 .

[28]  J. Yusta,et al.  Techno-economic modelling of water electrolysers in the range of several MW to provide grid services while generating hydrogen for different applications: A case study in Spain applied to mobility with FCEVs , 2019, International Journal of Hydrogen Energy.

[29]  Emanuela Colombo,et al.  Representation of Balancing Options for Variable Renewables in Long-Term Energy System Models: An Application to OSeMOSYS , 2019, Energies.

[30]  Stefan Reichelstein,et al.  Economics of converting renewable power to hydrogen , 2019, Nature Energy.

[31]  Matias Negrete-Pincetic,et al.  The impact of concentrated solar power in electric power systems: A Chilean case study , 2019, Applied Energy.

[32]  Keywan Riahi,et al.  The MESSAGEix Integrated Assessment Model and the ix modeling platform (ixmp): An open framework for integrated and cross-cutting analysis of energy, climate, the environment, and sustainable development , 2019, Environ. Model. Softw..

[33]  Izzat Iqbal Cheema,et al.  Operating envelope of Haber–Bosch process design for power-to-ammonia , 2018, RSC advances.

[34]  Samveg Saxena,et al.  Quantifying the flexibility of hydrogen production systems to support large-scale renewable energy integration , 2018, Journal of Power Sources.

[35]  Hannele Holttinen,et al.  Power-to-ammonia in future North European 100 % renewable power and heat system , 2018, International Journal of Hydrogen Energy.

[36]  José L. Rueda Torres,et al.  Integration of Power-to-Gas Conversion into Dutch Electrical Ancillary Services Markets , 2018 .

[37]  Hartmut Spliethoff,et al.  Current status of water electrolysis for energy storage, grid balancing and sector coupling via power-to-gas and power-to-liquids: A review , 2018 .

[38]  A. Hawkes,et al.  Future cost and performance of water electrolysis: An expert elicitation study , 2017 .

[39]  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).

[40]  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 .

[41]  Francois Bouffard,et al.  Flexibility Envelopes for Power System Operational Planning , 2014, IEEE Transactions on Sustainable Energy.

[42]  H. Rogner,et al.  Incorporating flexibility requirements into long-term energy system models – A case study on high levels of renewable electricity penetration in Ireland , 2014 .

[43]  Semida Silveira,et al.  OSeMOSYS: The Open Source Energy Modeling System: An introduction to its ethos, structure and development , 2011 .