<P> Hence researchers created the term proton - motive force (PMF), derived from the electrochemical gradient mentioned earlier . It can be described as the measure of the potential energy stored as a combination of proton and voltage (electrical potential) gradients across a membrane . The electrical gradient is a consequence of the charge separation across the membrane (when the protons H move without a counterion, such as chloride Cl). </P> <P> In most cases the proton - motive force is generated by an electron transport chain which acts as a proton pump, using the Gibbs free energy of redox reactions to pump protons (hydrogen ions) out across the membrane, separating the charge across the membrane . In mitochondria, energy released by the electron transport chain is used to move protons from the mitochondrial matrix (N side) to the stroma (P side). Moving the protons out of the mitochondrion creates a lower concentration of positively charged protons inside it, resulting in excess negative charge on the inside of the membrane . The electrical potential gradient is about - 170 mV, negative inside (N). These gradients - charge difference and the proton concentration difference both create a combined electrochemical gradient across the membrane, often expressed as the proton - motive force (PMF). In mitochondria, the PMF is almost entirely made up of the electrical component but in chloroplasts the PMF is made up mostly of the pH gradient because the charge of protons H is neutralized by the movement of Cl and other anions . In either case, the PMF needs to be greater than about 460 mV (45 kJ / mol) for the ATP synthase to be able to make ATP . </P> <P> The proton - motive force is derived from the Gibbs free energy . Let N denote the inside of a cell, and let P denote the outside . Then </P> <Dl> <Dd> Δ G = z F Δ ψ + R T ln ⁡ (X z +) N (X z +) P (\ displaystyle \ Delta \! G = zF \ Delta \! \ psi + RT \ ln (\ frac ((\ mathrm (X) ^ (z+)) _ (\ text (N))) ((\ mathrm (X) ^ (z+)) _ (\ text (P))))) </Dd> </Dl>

Explain the formation of atp by chemiosmosis in cellular respiration