Tobias Janoschka | Jena Flow Batteries: Organic molecules can degrade, so how can you build a 20-year battery with them?

What if you could build a grid-scale battery from the most abundant elements on Earth?

In a metal-free or organic flow battery, the core principle of storing energy in two separate liquids is maintained. However, instead of using metal ions like vanadium, the active materials are organic salts dissolved in water. These aqueous electrolytes are stored in tanks and pumped through a cell stack where the electrochemical charging and discharging reactions occur, leveraging the advantages of the flow battery architecture with a novel chemistry.

The primary advantage of this approach is supply security. The speaker uses a periodic table to visually demonstrate that the building blocks of their organic molecules are carbon, hydrogen, and nitrogen—some of the most abundant and easily accessible elements on Earth. This fundamentally de-risks the supply chain compared to batteries that rely on geographically concentrated or scarce metals.

This material advantage is further enhanced by the choice of precursors. The specific organic molecules used are synthesized from industrial commodities like acetone and ammonia, which are already manufactured on an enormous global scale. By design, this technology avoids any reliance on critical battery metals such as lithium, cobalt, or even vanadium, ensuring a stable and scalable material pipeline for gigawatt-hour scale deployments.

In this short video, you can learn:
* The fundamental operating principle of an organic redox flow battery.
* Why using organic molecules provides inherent supply chain security.
* How the technology avoids reliance on critical battery metals like vanadium or lithium.
📋 **Clip Abstract** This clip explains the core concept of a metal-free organic flow battery, where energy is stored in water-based solutions of organic salts. The primary advantage highlighted is the use of materials derived from the most abundant elements on Earth, ensuring a secure and scalable supply chain.
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How can you design a battery where you can upgrade its energy capacity without touching its power output?

The key architectural feature of a flow battery is the decoupling of power and energy. Power output is determined by the size and number of the electrochemical cell stacks, while the total energy capacity is a direct function of the volume of electrolyte stored in the tanks. This separation is a fundamental design advantage over monolithic battery architectures.

This decoupling makes the system uniquely and cost-effectively scalable for long-duration storage applications. To increase a system's storage duration from 4 hours to 8 or 12 hours, one simply increases the size or number of electrolyte tanks. The power conversion system (the stacks) remains unchanged, allowing for precise and economical tailoring of the battery to the specific duty cycle of an application.

This modularity also extends to maintenance and repair. A flow battery is not a sealed, monolithic device but rather an industrial system of accessible subsystems like pumps, pipes, sensors, and stacks. If a single component fails—for example, one cell stack—it can be isolated, removed, and replaced without decommissioning the entire system or losing the valuable electrolyte, which remains safely in the tanks.

In this short video, you can learn:
* The principle of decoupled power and energy in flow batteries.
* How to independently scale storage duration by simply adding more electrolyte.
* The advantage of modular design for simplified maintenance and repair.
📋 **Clip Abstract** This segment details the unique architectural benefits of flow batteries, focusing on the independent scaling of power and energy. This modularity allows for cost-effective long-duration storage and simplifies maintenance, as individual components can be repaired or replaced without affecting the entire system.
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