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The Solid Electrolyte Interphase (SEI) is a thin layer that forms on the negative electrode surface in lithium-ion batteries. While essential for stable operation, the SEI continues to grow throughout the battery’s lifetime, consuming lithium and increasing resistance. SEI growth is one of the most fundamental—yet still not fully understood—processes affecting battery lifespan.

What Is the SEI?

The Solid Electrolyte Interphase (SEI) is a thin layer that forms on the surface of the negative electrode (anode) in lithium-ion batteries. A similar process occurs on the positive electrode, but it has received much less attention. The SEI results from electrolyte decomposition and is crucial during the first few charging cycles—a stage known as formation—but it continues evolving throughout the battery’s lifetime.

Why the SEI Matters

The SEI acts as a protective barrier, preventing further electrolyte breakdown while allowing lithium ions to pass through.

Benefits of a Well-Formed SEI

BenefitDescription
Prevents electrolyte decompositionReduces unwanted side reactions
Regulates lithium-ion transportEnsures efficient charge and discharge cycles
Stabilizes the interfaceEnables long-term battery operation

The Problem: Continuous Growth

The SEI is not a static layer. Over time, it thickens due to continuous side reactions, trapping lithium ions and increasing resistance. This leads to capacity fade and power loss.

Modeling SEI Growth

Due to its complexity, SEI growth is not fully understood, and many different modeling approaches attempt to capture different aspects of the process. Typically, physics-based SEI models are defined by coupling additional equations on top of electrochemical models.

Reaction Equations

One set of equations describes the electrochemical reactions that create the SEI. Despite significant research efforts, the precise physics behind SEI formation remain an open question.
Many models assume a particular limiting factor for SEI growth—such as solvent diffusion or electron tunneling—so that other effects can be disregarded.

Porosity Changes

SEI growth also affects the porosity of the negative electrode, as it fills up void spaces originally meant for electrolyte penetration. Another equation is needed to track porosity changes over time.