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Journal articleHawker G, Bell K, Bialek J, et al., 2024,
Management of extreme weather impacts on electricity grids: an international review
, PROGRESS IN ENERGY, Vol: 6 -
Journal articleChu Z, Cui G, Teng F, 2024,
Scheduling of Software-Defined Microgrids for Optimal Frequency Regulation
, IEEE TRANSACTIONS ON SUSTAINABLE ENERGY, Vol: 15, Pages: 1715-1728, ISSN: 1949-3029 -
Journal articleFrolke L, Prat E, Pinson P, et al., 2024,
On the efficiency of energy markets with non-merchant storage
, ENERGY SYSTEMS-OPTIMIZATION MODELING SIMULATION AND ECONOMIC ASPECTS, ISSN: 1868-3967 -
Journal articleChaudhuri B, Ramasubramanian D, Matevosyan J, et al., 2024,
Rebalancing needs and services for future grids: system needs and service provisions with increasing shares of inverter-based resources
, IEEE Power and Energy Magazine, Vol: 22, Pages: 30-41, ISSN: 1540-7977The primary objective of electricity grids is to reliably meet the electricity demand at a minimum cost. This objective can be broken down into a set of needs that are met through services. These services are procured by mandating them either in grid codes or via market mechanisms. While grids in different countries/regions share common features in terms of needs and services, there are variations arising in physical, regulatory, and policy contexts. With the increased use of inverter-based resources (IBRs), such as wind and solar photovoltaic (PV) power and battery energy storage systems (BESSs), grids are undergoing changes that are altering the balance between needs and services. This balance is crucial in managing changes that will ensure that grids will continue to be able to meet demands. As increasingly more synchronous machines (SMs) are replaced by IBRs, the services inherently provided by the remaining SMs are dwindling, thus requiring the IBRs to contribute where they can.
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Journal articleXu L, Feng K, Lin N, et al., 2024,
Resilience of renewable power systems under climate risks
, Nature Reviews Electrical Engineering, Vol: 1, Pages: 53-66, ISSN: 2948-1201Climate change is expected to intensify the effects of extreme weather events on power systems and increase the frequency of severe power outages. The large-scale integration of environment-dependent renewables during energy decarbonization could induce increased uncertainty in the supply–demand balance and climate vulnerability of power grids. This Perspective discusses the superimposed risks of climate change, extreme weather events and renewable energy integration, which collectively affect power system resilience. Insights drawn from large-scale spatiotemporal data on historical US power outages induced by tropical cyclones illustrate the vital role of grid inertia and system flexibility in maintaining the balance between supply and demand, thereby preventing catastrophic cascading failures. Alarmingly, the future projections under diverse emission pathways signal that climate hazards — especially tropical cyclones and heatwaves — are intensifying and can cause even greater impacts on the power grids. High-penetration renewable power systems under climate change may face escalating challenges, including more severe infrastructure damage, lower grid inertia and flexibility, and longer post-event recovery. Towards a net-zero future, this Perspective then explores approaches for harnessing the inherent potential of distributed renewables for climate resilience through forming microgrids, aligned with holistic technical solutions such as grid-forming inverters, distributed energy storage, cross-sector interoperability, distributed optimization and climate–energy integrated modelling.
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Conference paperGorbunov A, Peng JC-H, Bialek J, et al., 2024,
Can Center-of-Inertia Model be Identified From Ambient Frequency Measurements?
, IEEE-Power-and-Energy-Society General Meeting (PESGM), Publisher: IEEE, ISSN: 1944-9925 -
Journal articleVeers P, Dykes K, Basu S, et al., 2022,
Grand Challenges: wind energy research needs for a global energy transition
, Wind Energy Science, Vol: 7, Pages: 2491-2496, ISSN: 2366-7443Wind energy is anticipated to play a central role in enabling a rapid transition from fossil fuels to a system based largely on renewable power. For wind power to fulfill its expected role as the backbone – providing nearly half of the electrical energy – of a renewable-based, carbon-neutral energy system, critical challenges around design, manufacture, and deployment of land and offshore technologies must be addressed. During the past 3 years, the wind research community has invested significant effort toward understanding the nature and implications of these challenges and identifying associated gaps. The outcomes of these efforts are summarized in a series of 10 articles, some under review by Wind Energy Science (WES) and others planned for submission during the coming months. This letter explains the genesis, significance, and impacts of these efforts.
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Journal articleDeakin M, Taylor PC, Bialek J, et al., 2022,
Design and operation of Hybrid Multi-Terminal Soft Open Points using Feeder Selector Switches for flexible distribution system interconnection
, ELECTRIC POWER SYSTEMS RESEARCH, Vol: 212, ISSN: 0378-7796- Cite
- Citations: 8
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Journal articleMorsy B, Hinneck A, Pozo D, et al., 2022,
Security constrained OPF utilizing substation reconfiguration and busbar splitting
, ELECTRIC POWER SYSTEMS RESEARCH, Vol: 212, ISSN: 0378-7796- Cite
- Citations: 9
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