Providing a platform for large-scale batteries facilitating their participation into the flexibility provision in a market-based manner

A joint project between Johns Hopkins University and University of Cologne to analyse technically and economically the integration of GH2 into stochastic producers. https://github.com/hybrid-energy-systems 

A practical European project on P2P energy trading and flexibility management.

• Liquidity-Pool-Based Automated Market Maker for Energy Sharing:

Designing a decentralized market mechanism inspired by concepts from decentralized finance (DeFi), enabling efficient and transparent energy trading. This mechanism ensures liquidity in local energy markets, providing a scalable solution for energy transactions among prosumers while reducing operational complexities.

• Distributed Optimization for Flexibility Markets:

My research also explores distributed optimization algorithms to enhance the operation of flexibility markets. These algorithms empower communities to contribute their flexible resources, such as energy storage and electric vehicles, to stabilize the grid. The market design ensures equitable participation while addressing grid constraints in real time.

•  AI-Powered Tools for Prosumers’ Participation:

Leveraging artificial intelligence, we're developing tools to optimize prosumers' participation in the energy grid. These tools guide users in making informed decisions about energy usage, storage, and trading, maximizing their economic and environmental benefits while ensuring grid stability.