Electrode array and method for operating the electrode array

The invention claimed is: 1. An electrode array for cyclic reduction and oxidation of a redox species in an electrolyte, comprising a control electrode and a collector electrode, wherein both the control and the collector electrodes are disposed on an insulating substrate and connected to a counter electrode for application of a voltage and further comprising a separate reference electrode configured to measure potentials at least at the control electrode and the collector electrode, wherein, a) the control electrode is configured for reacting the redox species for cyclic electron transport between the control and the collector electrodes; and b) the collector electrode is disposed opposite the control electrode, wherein a layer structure composed of a second insulator, having a charge transfer mediator disposed thereon, is additionally disposed on a side of the collector electrode located opposite the insulating substrate for reacting the redox species, wherein the control electrode does not have the second insulator and the charge transfer mediator disposed thereon, and further wherein the charge transfer mediator and the redox species are both preselected such that the preselected charge transfer mediator and the preselected redox species have a respective standard electrode potential that allows a charge transfer along an electrochemical series as a function of the voltage that is applied by the counter electrode to the control electrode, and by the counter electrode to the collector electrode. 2. The electrode array according to claim 1 , wherein the control and the collector electrodes are made of the same material. 3. A method comprising: providing an electrode array, for cyclic reduction and oxidation of a redox species in an electrolyte, comprising a control electrode and a collector electrode, wherein both the control and the collector electrodes are disposed on an insulating substrate and connected to a counter electrode for application of a voltage, wherein, a) the control electrode is configured for reacting the redox species for cyclic electron transport between the control and the collector electrodes; and b) the collector electrode is disposed opposite the control electrode, wherein a layer structure composed of a second insulator, having a charge transfer mediator disposed thereon, is additionally disposed on a side of the collector electrode located opposite the insulating substrate for reacting the redox species, and wherein the control electrode does not have the second insulator and the charge transfer mediator disposed thereon; selecting the charge transfer mediator and the redox species such that the selected charge transfer mediator and the redox species have a respective standard electrode potential that allows a charge transfer along an electrochemical series as a function of the voltage that is applied by the counter electrode to the control electrode, and by the counter electrode to the collector electrode; selecting the redox species such that the redox species has a more negative standard electrode potential than the standard electrode potential of the charge transfer mediator, the redox species being added to the electrolyte in oxidized form, with a potential that is more negative than the standard electrode potential, of the redox species being applied to the control electrode, and a potential that is more positive than the standard electrode potential of the charge transfer mediator being applied to the collector electrode; and cyclically reacting the redox species at the control electrode and the collector electrode. 4. The electrode array according to claim 1 , wherein the control electrode and the collector electrode have a constant distance of less than 10 μm. 5. The electrode array according to claim 1 , wherein the control and the collector electrodes are arranged in the same plane on the substrate insulator, or on top of each other. 6. The electrode array according to claim 1 , wherein the charge transfer mediator comprises 11-undecanethio ferroncene (Fc) and the second insulator comprises hexanedecanethio (HDT). 7. The electrode array according to claim 2 , wherein the same material of the control electrode and the collector electrode is gold and the control electrode does not have any further molecule layers thereon. 8. A method comprising: providing an electrode array, for cyclic reduction and oxidation of a redox species in an electrolyte, comprising a control electrode and a collector electrode, wherein both the control and the collector electrodes are disposed on an insulating substrate and connected to a counter electrode for application of a voltage, wherein, a) the control electrode is configured for reacting the redox species for cyclic electron transport between the control and the collector electrodes; and b) the collector electrode is disposed opposite the control electrode, wherein a layer structure composed of a second insulator, having a charge transfer mediator disposed thereon, is additionally disposed on a side of the collector electrode located opposite the insulating substrate for reacting the redox species, and wherein the control electrode does not have the second insulator and the charge transfer mediator disposed thereon; selecting the charge transfer mediator and the redox species such that the selected charge transfer mediator and the redox species have a respective standard electrode potential that allows a charge transfer along an electrochemical series as a function of the voltage that is applied by the counter electrode to the control electrode, and by the counter electrode to the collector electrode; selecting the redox species such that the redox species has a more positive standard electrode potential than the standard electrode potential of the charge transfer mediator, the redox species being added to the electrolyte in reduced form, with a potential that is more positive than the standard electrode potential of the redox species being applied to the control electrode, and a potential that is more negative than the standard electrode potential of the charge transfer mediator being applied to the collector electrode; and cyclically reacting the redox species at the control electrode and the collector electrode. 9. A method comprising: providing an electrode array, for cyclic reduction and oxidation of a redox species in an electrolyte, comprising a control electrode and a collector electrode, wherein both the control and the collector electrodes are disposed on an insulating substrate and connected to a counter electrode for application of a voltage, wherein, a) the control electrode is configured for reacting the redox species for cyclic electron transport between the control and the collector electrodes; and b) the collector electrode is disposed opposite the control electrode, wherein a layer structure composed of a second insulator, having a charge transfer mediator disposed thereon, is additionally disposed on a side of the collector electrode located opposite the insulating substrate for reacting the redox species, and wherein the control electrode does not have the second insulator and the charge transfer mediator disposed thereon; selecting the charge transfer mediator and the redox species such that the selected charge transfer mediator and the redox species have a respective standard electrode potential that allows a charge transfer along an electrochemical series as a function of the voltage that is applied by the counter electrode to the control electrode, and by the counter electrode to the collector electrode; and cyclically reacting the redox species at the control electrode and the collector electrode and selecting an upper