Electrochemical sensor utilising a dual redox system contained within a single molecule

The invention claimed is: 1. An electrochemical sensor for pH of aqueous liquid comprising a solid, electrically conductive substrate, and two redox systems both located on a surface of the substrate wherein a first redox system is selected from the group consisting of aromatic quinones, aromatic diamines, catechols, phenothiazinium dyes and hydroxylamino-substituted aromatic groups and displays a reversible reduction or oxidation at a voltage which is sensitive to the concentration of hydrogen ions, and a second redox system is a metallocene which displays a reversible reduction or oxidation at a voltage which is essentially insensitive to the concentration of hydrogen ions wherein the first and second redox systems are directly connected together by a bond which consists of only one uninterrupted covalent bond extending from an aromatic ring of the first redox system to a ring of the metallocene which is the second redox system so that both redox systems are contained in the same chemical compound which is a compound of determinate structure with a molecular weight of less than 1000 and which contains no more than three instances of each redox system, wherein the first and second redox system each has a peak potential on its voltammetric redox wave at a respective pH, and wherein the peak potentials of the first and second redox systems do not overlap over pH range 1.0-9.9. 2. A sensor according to claim 1 wherein the chemical compound of determinate structure is monomeric with a molecular weight of less than 500. 3. A sensor according to claim 2 wherein the chemical compound contains only a single instance of each redox system. 4. A sensor according to claim 1 wherein the substrate is carbon based and the compound of determinate structure is bound to the substrate through covalent chemical bonds. 5. A sensor according to claim 1 wherein the first redox system is an aromatic quinone. 6. A sensor according to claim wherein the first redox system is a hydroxylamino-substituted aromatic moiety. 7. A sensor according to claim 6 wherein the first redox system is provided as a nitro-substituted aromatic moiety. 8. A sensor according to claim 1 wherein at least one of the redox systems is effective to catalyze an oxidation or reduction of a second species to be detected. 9. A sensor according to claim 8 wherein the second species is sulfide or oxygen. 10. A sensor according to claim 1 together with means to apply variable voltage to the sensor and measure current while the voltage is systematically varied. 11. A sensor according to claim 1 wherein the first redox system is selected from the group consisting of anthraquinone and its derivatives, phenanthrenequinone and its derivatives, phenothiazinium dyes and their derivatives, hydroxylaminobenzene and its derivatives, and nitrophenyl and its derivatives. 12. A sensor according to claim 8 wherein the sensor is for pH and oxygen, or for pH and sulfide, or for pH, oxygen and sulfide. 13. An electrochemical sensor for pH of aqueous liquid in contact with the sensor comprising a solid, electrically conductive substrate, and two redox systems both located on a surface of the substrate wherein a first redox system comprises at least one aromatic ring and displays a reversible reduction or oxidation at a voltage which is sensitive to the concentration of hydrogen ions, and a second redox system is a metallocene which displays a reversible reduction or oxidation at a voltage which is essentially insensitive to the concentration of hydrogen ions wherein the first and second redox systems are directly connected together by a bond which consists of only one uninterrupted covalent bond extending from an aromatic ring of the first redox system to a ring of the metallocene which is the second redox system so that both redox systems are contained in the same chemical compound which is a compound of determinate structure with a molecular weight of less than 1000 and which contains no more than three instances of each redox system, and wherein the substrate comprises conductive carbon and the compound of determinate structure is immobilized on the conductive carbon substrate. 14. A sensor according to claim 13 wherein the first redox system is an aromatic quinone or a hydroxylamino-substituted aromatic moiety. 15. A sensor according to claim 13 wherein the first redox system is selected from the group consisting of anthraquinone and its derivatives, phenanthrenequinone and its derivatives, phenothiazinium dyes and their derivatives, hydroxylaminobenzene and its derivatives, and nitrophenyl and its derivatives. 16. An electrochemical sensor for pH of aqueous liquid comprising a solid, electrically conductive substrate and a chemical compound with a molecular weight of less than one thousand located on a surface of the substrate wherein the chemical compound consists of a first redox system which is selected from the group consisting of aromatic quinones, aromatic diamines, catechols, phenothiazinium dyes and hydroxylamino-substituted aromatic groups and displays a reversible reduction or oxidation at a voltage which is sensitive to the concentration of hydrogen ions, and a second redox system which is a metallocene and which displays a reversible reduction or oxidation at a voltage which is essentially insensitive to the concentration of hydrogen ions wherein the first and second redox systems are directly connected together and the connection between them consists of only one covalent bond which extends without interruption from an aromatic ring of the first redox system to a ring of the metallocene which is the second redox system, and wherein the first and second redox system each has a peak potential on its voltammetric redox wave at a respective pH, and wherein the peak potentials of the first and second redox systems do not overlap over pH range 1.0-9.9. 17. An electrochemical sensor according to claim 16 , wherein the first redox system is hydroxylamino substituted phenyl. 18. An electrochemical sensor according to claim 16 , wherein the chemical compound is selected from hydroxylaminophenyl ferrocene, hydroxylaminophenyl diethyl ferrocene and hydroxylaminophenyl t-butyl ferrocene.