reduction potential

But it has a more negative reduction potential from its 3+ ion.

In fact, you could use any metal which has a large positive reduction potential, including platinum.

These are simply the negative of standard reduction potentials, so it is not a major problem in practice.

The reference electrode is a half cell with a known reduction potential.

The following table provides the reduction potentials of the indicated reducing agent at 25 C.

The driving force is the difference in reduction potentials between the two dissimilar metals.

By comparison, the standard reduction potential for ferrodoxins is about 430 mV.

The standard reduction potentials for aqueous solutions are shown in the next table.

Like pH, the reduction potential represents an intensity factor.

Alternatively, it may be necessary to convert measurements to the standard reduction potential for reporting purposes.

This weakens the reduction potential of the compound and the two developers have markedly different character.

The reduction potential of H+ to H2 in acidic conditions is +0.00, making the reaction occur easily.

The oxidation potential for a particular electrode is just the negative of the reduction potential.

Selenocysteine has both a lower pKa (5.47) and a higher reduction potential than cysteine.

The reduction potential is a measure of the tendency of the oxidizing agent to be reduced.

Agent 1 has lower reduction potential but much higher adsorption to the silver halide crystals.

The table below shows a few reduction potentials that could easily be changed to oxidation potential by simply reversing the sign.

The one-electron reduction potential of a molecule can be used to obtain an electron affinity.

The measured potential difference is around 1.67 V per cell (slightly less than that predicted from the standard reduction potentials).

The reduction potential is an intensive property.

Therefore, standard electrode potential is commonly written as standard reduction potential.

This method can reveal the reduction potential of an analyte and its electrochemical reactivity.

Phosphines are completely absent from living systems and do not reduce disulfide bonds despite mild reduction potential.

The calcium does not enter into the reaction because its reduction potential of 2.87 volts is higher than that of sodium.

To tell which is the strongest reducing agent, one can change the sign of its respective reduction potential to make it oxidation potential.