Internal resistance of a battery cell

AI Thread Summary
When a battery cell discharges, the internal resistance typically increases, leading to a constant drop in potential difference across the cell. Various models exist to represent battery behavior, with some employing a constant or variable electromotive force (EMF) alongside a variable internal resistance. Different battery chemistries require distinct modeling approaches, as no single model universally applies to all types. The EMF is defined as the potential difference between the terminals when they are externally connected. Understanding these dynamics is crucial for accurately assessing battery performance.
Cici2017
if a cell is running down, there would be a constant drop in p.d. across the cell, does the internal resistance of the cell increase or decrease?
 
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There are lots of ways to model a battery cell. One way is with a constant or variable EMF and a variable internal resistance that increases as the cell discharges. That's not a bad model for alkaline cells.

However different types of cell (eg different chemistry) need different models. There isn't a one model that fits the behaviour of all cells.
 
Emf of a cell is the potential difference between it's terminals when terminals are connected externally.
∆V=E - I*r
E=emf
I=current
r=internal resistance
 
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