# Why don't the electrons move through the electrolyte (instead of the circuit) in a galvanic cell?

I was learning about galvanic cells and I had a problem understanding why electrons do not travel through the electrolyte solutions themselves, instead preferring to travel through metals. Can electrons travel through an electrolytic solution?

Imagine a galvanic cell, without the wiring between the two electrodes and instead we only have the salt bridge. Won't the electrons (although it is very unfavorable to happen) travel through the salt bridge and the solutions? In other terms will the transformation of the electrodes occur?

Not in water. Free electron in water is really unfavorable, so no significant concentration of them can be generated chemically, and it almost immediately reduces water itself to hydrogen (but I heard rumors about generation of solvated electrons in water in very special experiment with short half-life)

In liquid $\ce{NH_3}$, however, solvated electrons can occur, so self-discharge of galvanic cells with $\ce{NH_3}$-based electrolyte may occur through travel of electrons via electrolyte.

• But we have ions in water. So can't the water act as a conductor in this case? Sep 13, 2018 at 21:50

You're questioning the intuitive disconnect caused by most galvanic cell drawings which seem to assume the electrolyte solution in the salt bridge does not conduct electricity, so let's investigate.

Imagine a Zn/Cu$$^{2+}$$ cell with electrodes 5 cm apart in a 3.5% NaCl solution with a tube (1 cm$$^2$$ cross-section) of solution as the salt bridge for balancing charge.

The electrical resistance (R = $$\rho$$l/A) of our NaCl 0.05 m x 1 cm$$^2$$ salt bridge solution is:

$$\frac{0.2 \ ohms*m}{} * \frac{0.05 \ * m \ (length)}{10^{-4}m^2 \ (cross-section \ area)}= 100 \ ohms$$

Considering the predicted EMF of 1.1 Volts for this cell, the expected current ($$I = V/R$$) through the salt bridge is: $$1.1V/100 \ ohms \ = 0.011 \ amps$$

This current may be negligible in a galvanic cell drawing compared to the current through some wire or low-resistance load. However, this would make a terrible battery for most common purposes as a typical AA battery (3000 mAh) would go completely dead in less than 2 weeks if it actually leaked at this rate!

It seems then your intuition is basically right... until you understand what the models leave out. In real alkaline battery designs, the cathode, electrolyte, and anode are sandwiched together very closely with a very large surface area, yielding excellent conductivity through electrolyte (and therefore very low resistance). However, these layers are separated by a membrane which allows ions through but has a very high resistance to electric current.

Sources: https://www.thoughtco.com/table-of-electrical-resistivity-conductivity-608499 (seawater resistance) https://en.wikipedia.org/wiki/Alkaline_battery (alkaline battery design)

• This is a much more satisfying answer than the accepted one. Thanks! Sep 23, 2020 at 12:36

Electron's can travel through the electrolyte solution, however electrons take the pathway with the lowest resistance, the solution has a relatively higher resistance compared to the outer circuit. Hence the electron takes the path of the outer circuit.

Electrons cannot survive in aqueous state. Being a charged subatomic particle, the electron has to stay close to protons which are located at the center of the atom. Hence, the electron can move from one atom to another which are closely-packed, what we have in a solid.

Maybe just think of it as the electrons hitching a ride through the electrolyte on the relatively giant and mobile atoms that make up ions in the solution. If you really wanted to force those electrons to travel on their own through the electrolyte you'd have to crank up the voltage big time. Thousands of volts would be needed to provide the electrons with enough energy to rip through the electrolyte (i.e. dielectric breakdown).

Another way to get electricity to flow through an electrolyte, although still not electrons flowing, is to impose an AC current across a cell. At high enough frequency (usually in kHz range) current can short through the capacitance at each electrode. This is typically how conductivity measurements are made on liquids.