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The reduction potential plus oxidation potential is negative.
The element with the greater reduction potential is the one that is reduced.
The element with the greater reduction potential is the one that is reduced.
The Redox 'Battlefield' is the Redox reactions mediated by bacteria.
strong dependence of electrode potential on pH, pH-dependent redox potential, Ernst equation now includes the H+-acidity. Reduction potential thus decreases by 2.3RT/F = 0.059 V per pH unit, The pH dependence is given by -(0.059 m/n)pH(n=numbre of electrons, m=number of H+) in the equation Aox + mH+ + ne ↔ AredH2
by the use of ELECTRODES.
. The reaction will be spontaneous.
The reduction potential plus oxidation potential is negative.
Standard electrode potential is a redox electrode. This is the forms the basis of the thermodynamic scale.
The element with the greater reduction potential is the one that is reduced.
The element with the greater reduction potential is the one that is reduced.
The element with the greater reduction potential is the one that is reduced.
iron
Dilute sulfuric acid H2SO4 is an indifferent acid to oxidising substances, while HCl (potential +1.36V) is a reductant and HNO3 (potential +0.96V) is an oxidant.
The Redox 'Battlefield' is the Redox reactions mediated by bacteria.
strong dependence of electrode potential on pH, pH-dependent redox potential, Ernst equation now includes the H+-acidity. Reduction potential thus decreases by 2.3RT/F = 0.059 V per pH unit, The pH dependence is given by -(0.059 m/n)pH(n=numbre of electrons, m=number of H+) in the equation Aox + mH+ + ne ↔ AredH2
One way to quantify whether a substance is a strong oxidizing agent or a strongreducing agent is to use the oxidation-reduction potential or redox potential. Strong oxidizing agents have low electron-transfer potential.