EESAT 2027 (IEEE PES Electrical Energy Storage Applications and Technologies) is an academic conference held in St. Pete Beach, Florida, USA on 2027-01-11. The paper submission deadline is 2026-07-27. Acceptance notifications are sent on 2026-09-14.
The IEEE PES Electrical Energy Storage Applications and Technologies (EESAT 2027) will be held on January 11th and 12th 2027, at the Sirata Beach Resort in St. Pete Beach, Florida. This technical conference will be co-located with the IEEE Energy Storage and Stationary Battery (ESSB) Committee’s winter meeting to be held January 13th through 15th.
The Electrical Energy Storage Applications and Technologies (EESAT) conference is the premier technical forum for presenting advances in energy storage technologies and applications since 2001. This forum is organized by the IEEE ESSB Committee, a part of the IEEE Power and Energy Society (PES). We are sponsored by PES with additional support from the Department of Energy Office of Electricity and Sandia National Laboratories.
The program covers all aspects of energy storage technologies and systems from molecules to megawatts. This year we will be highlighting innovations in technologies and applications that will address needs of today’s electric grid revolution with an aim to ensure a secure, resilient, and reliable electric power system. Abstracts and papers with broad scope on energy storage technologies, applications, and controls in real-world applications, are particularly welcome in addition to other works addressing the energy storage supply chai, cost-effectiveness, and operations.
The technical committee welcomes papers on novel storage technologies. Examples include expanding lithium and other intercalation topologies, flow battery designs, other zinc derivatives, as well as flywheels, green hydrogen as energy storage, pumped storage, and compressed air energy storage (CAES). We also welcome papers on advances in power conversion systems for energy storage including novel materials, architectures, control systems, and applications. Novel approaches to energy storage such as demand response, long duration, second-use battery pros and cons will also be considered. At the same time, the forum highlights advances in energy management and device management systems that maximize lifetime of systems while enabling safe and reliable operation, and advances in markets, standards, and policy that unlock energy storage as a critical enabler of the clean energy transition.
Accepted papers will be presented in one of two formats: oral presentations or poster session presentations. Exact presentation lengths will be determined based on the total number of papers accepted.
This conference aims to foster a multi-discipline, systems oriented, collaborative environment for energy storage researchers and professionals engaged in the technical aspects of energy storage to share ideas and find collaborative ways to solve big problems together. We will cultivate a community of practice around energy storage research that cuts across the boundaries that normally divide technical societies and journals. EESAT seeks to address all aspects of the storage of electrical energy including the technology itself and how it is used in the real world to solve problems, improve grid resilience, and make the grid a more secure and efficient system.
Technical Scope
The Conference Organizing Committee invites researchers and practitioners to submit papers for review and possible presentation.
The conference scope covers the following general topics:
Energy Storage Controls and Applications, some examples include:
Interactions with the transportation sector
Vehicle-to-grid applications
Market structures, infrastructure, and incentives
Resource availability and alternatives
Second life battery applications and management
Energy Storage for Data Centers and Large Loads
AI/Machine Learning-based controls and operation
Market applications
Energy market participation models
Ancillary service market participation models
Energy Equity and Environmental Justice Applications
Expanding access to electricity
Peaker plant replacement
Resilience Applications
Special use during natural disasters
Black-start and service restoration
Microgrid and novel UPS for critical infrastructure
Grid stability, e.g.:
primary frequency response and,
small signal stability
Energy Storage Security
Communications and security standards
Supply chain security considerations
Cybersecurity tool development and/or demonstration
Energy Storage System Performance, Safety, and Degradation
Real-world applications and/or comparisons to laboratory studies
Implications of degradation on technoeconomic analyses and ES management systems
Analysis of full ES lifecycles including end-of-life
Markets, Standards, and Policy
New market structures that better utilize storage
Impacts of state/national/international policy on storage
Impacts of new industry standards on safety, interoperability, and integration
Expansion planning with energy storage
Case studies
Energy Storage and Device Management Systems
Optimal control systems
Integration with renewable DER
Device aggregation and coordination
Advanced battery management
Power Conversion Systems for Storage
Advanced PE materials
New PE architectures
Advance power conversion control
Power quality applications of energy storage
Artificial inertia and virtual oscillator control
Energy Storage Technologies, some examples include:
Electrochemical
Lithium batteries
Lead acid batteries
Sodium batteries
Mechanical
Compressed air
Pumped hydro
Flywheels
Gravity
Thermal
Molten salt
Ice
Integration with existing power plants
Electrical
Ultra-capacitors
Long Duration ES
Flow batteries
Assessment of resource availability and synergies between technologies
Technology advancements, economic predictions, future grid impacts
Green hydrogen production and use
Aún no hay comentarios.