Alkalinity sensor

What is claimed is: 1. A method for determining the alkalinity of an aqueous sample using an alkalinity sensor, comprising: monitoring the pH of an aqueous sample using a pH sensor in a sample cell, the pH sensor including a pH sensor electrode made of boron-doped diamond; controlling, using a peristaltic pump, a flow of the aqueous sample between the pH sensor and a boron-doped diamond hydronium generator, wherein the pH sensor and the boron-doped diamond hydronium generator each form a portion of a lumen to form a path for the flow of the aqueous sample; generating hydronium ions, using the boron-doped diamond hydronium generator, in the aqueous sample in the sample cell, the boron-doped diamond hydronium generator including a boron-doped diamond hydronium-generating electrode, wherein the alkalinity sensor comprises at least one counter electrode and at least one reference electrode separated from the sample cell by a restrictive conduit, wherein the at least one counter electrode and the at least one reference electrode are placed at a position relative to the aqueous sample from the group consisting of: fore and aft; changing the pH of the aqueous sample by causing the boron-doped diamond hydronium generator to generate a number of hydronium ions in the aqueous sample; quantifying and converting a current or charge to the number of hydronium ions produced to an end point of an electrochemical titration, the end point correlating to the alkalinity of the aqueous sample; and analyzing the alkalinity of the aqueous sample based on the quantified number of hydronium ions and the resulting change in pH monitored by the pH sensor. 2. The method of claim 1 , wherein the hydronium-generating electrode and the pH sensor electrode are on a unitary substrate. 3. The method of claim 1 , wherein the hydronium-generating electrode and the pH sensor electrode comprise boron-doped diamond on a single substrate. 4. The method of claim 1 , wherein the pH sensor electrode comprises a disc of boron-doped diamond and the hydronium-generating electrode comprises a plate spaced apart from the pH sensor. 5. The method of claim 1 , wherein the pH sensor electrode comprises a disc of boron-doped diamond and the hydronium-generating electrode comprises an open ring surrounding the pH sensor. 6. The method of claim 1 , wherein the pH sensor electrode comprises a first plate of boron-doped diamond and the hydronium-generating electrode comprises a second plate of boron-doped diamond spaced apart from the first plate. 7. The method of claim 1 , wherein the hydronium-generating electrode comprises a plate having an aperture and the pH sensor electrode is located within the aperture. 8. The method of claim 1 , wherein the boron-doped diamond hydronium generator has more than one hydronium-generating electrode. 9. The method of claim 1 , wherein the pH sensor electrode, the boron-doped diamond hydronium generator and a controller are part of a potentiostat and wherein the pH sensor electrode is a first working electrode of a bipotentiostat and the hydronium generating electrode is a second working electrode of the bipotentiostat.