<P> In a biological membrane, the reversal potential (also known as the Nernst potential) of an ion is the membrane potential at which there is no net (overall) flow of that particular ion from one side of the membrane to the other . In the case of post-synaptic neurons, the reversal potential is the membrane potential at which a given neurotransmitter causes no net current flow of ions through that neurotransmitter receptor's ion channel . </P> <P> In a single - ion system, reversal potential is synonymous with equilibrium potential; their numerical values are identical . The two terms refer to different aspects of the difference in membrane potential . Equilibrium refers to the fact that the net ion flux at a particular voltage is zero . That is, the outward and inward rates of ion movement are the same; the ion flux is in equilibrium . Reversal refers to the fact that a change of membrane potential on either side of the equilibrium potential reverses the overall direction of ion flux . </P> <P> The reversal potential is often called the "Nernst potential", as it can be calculated from the Nernst equation . Ion channels conduct most of the flow of simple ions in and out of cells . When a channel type that is selective to one species of ion dominates within the membrane of a cell (because other ion channels are closed, for example) then the voltage inside the cell will equilibrate (i.e. become equal) to the reversal potential for that ion (assuming the outside of the cell is at 0 volts). For example, the resting potential of most cells is close to the K (potassium ion) reversal potential . This is because at resting potential, potassium conductance dominates . During a typical action potential, the small resting ion conductance mediated by potassium channels is overwhelmed by the opening of a large number of Na (sodium ion) channels, which brings the membrane potential towards the reversal potential of sodium . </P>

When will the resting membrane potential be equal to the equilibrium potential of an ion