Different sizes have different amount of energy given (expressed in mAh), but the voltage is the same because internally they have the same cell structure with the same materials.

Voltage is how hard a battery pushes. You want fairly standard and specific voltages because most electronics and machines take a specific voltage. You might change the cell size to fit more reactants(like having a bigger gas tank), to allow the cell to fit in a different shape (cube cell vs a coin cell) or because you want to fit a different chemistry inside the cell (some chemistries last longer, are more resistant to colder temperatures, are more rechargeable or are lighter)

Dry battery cells use chemicals to produce electricity. These batteries come in different sizes, but they all have the same voltage, which is 1.5 volts.

The reason for this is that the voltage of a battery is determined by the chemicals inside the battery and how they interact with each other. Different sizes of dry cell batteries use the same chemicals, so they all have the same voltage.

The size of the battery does not affect its voltage, but it does affect how much electricity the battery can produce. A bigger battery has more space for chemicals, so it can produce more electricity than a smaller battery. This is why bigger batteries are often used in devices that need a lot of power, like flashlights or radios.

Think of electricity like it’s water in a pipe. The pipe represents the wire that the electricity travels through. Electrical current is analogous to how much water is flowing through the pipe over a period of time. Electrical voltage is analogous to water pressure in the pipe. Like, if the pipe travels vertically for a while, the water at the bottom of that vertical run of pipe will be at higher pressure than the water at the top. That difference in pressure between the top and bottom is analogous to the voltage across a battery. It’s basically how forcefully the electricity is being pushed through the wire.

Now imagine that this whole system of water and pipes is being fed by a tank of water. The water slowly empties out of the tank, and flows through the pipes. When the tank is empty, no more water flows through the pipes. As you can probably imagine, the tank is analogous to the battery.

So, imagine you have two different water systems with pipes and tanks. They’re identical except one has a much larger tank of water than the other one. The water pressure in the pipes is the same, and so is the rate of water flowing through the pipes. However, the system with the larger tank will take a lot longer to empty out.

This is the same with different size batteries. You can have a AAA battery and a D battery, and they have 1.5 volts across their terminals. If you hook them both up to a circuit, they’ll both cause the same amount of electricity to flow through that circuit. However, the D battery will last a whole lot longer than the AAA battery. That’s the only difference.

Battery capacity is usually expressed in mAh (milli-amp hours). Milli-amps are a measure of electrical current. So, you multiply the number of milli-amps the battery is putting out times the number of hours that it can put out that current, and that’s mAh. If the battery can put out 200 mA for 1 hour, that’s 200 mAh. If it can put out 100 mA for 6 hours, that’s 600 mAh.

AAA batteries have a capacity of 1200 mAh. AA batteries are 2000-3000 mAh. D batteries are usually 8000+ mAh (some types are even closer to 20,000 mAh). They all have 1.5 volts across their terminals, meaning they all push electricity through the circuit with the same force, but some have bigger “electron tanks” than others.