Multi-component eluent generating system and method

What is claimed is: 1. An electrolytic eluent generating device configured to generate at least two different generants, in which the at least two different generants include a first generant and a second generant, where a first generant concentration and a second generant concentration are both controllable as a function of time, the electrolytic eluent generating device comprising; a) a first eluent generator configured to i) receive a liquid from a pump; ii) add the first generant to the liquid; and iii) output the liquid that includes the first generant, in which the first eluent generator comprises: iv) a first ion source reservoir including a source of cations or anions; v) a first generation chamber including an inlet configured to receive the liquid and an outlet configured to output the liquid that includes the first generant; vi) a first ion exchange barrier at least partly disposed between the first ion source reservoir and the first generation chamber; vii) a first electrode in electrical communication with the first ion source reservoir; and viii) a second electrode in electrical communication with the first generation chamber; and b) a second eluent generator configured to i) receive the liquid from the first eluent generator; ii) add the second generant to the liquid; and iii) output the liquid that includes the first generant and the second generant, in which the second eluent generator comprises: iv) a second ion source reservoir including a source of cations or anions; v) a second generation chamber including an inlet configured to receive the liquid from the first eluent generator and an outlet configured to output the liquid that includes the first generant and the second generant; vi) a second ion exchange barrier at least partly disposed between the second ion source reservoir and the second generation chamber; vii) a third electrode in electrical communication with the second ion source reservoir; and vii) a fourth electrode in electrical communication with the second generation chamber, in which the first and second eluent generators together have a dead volume ranging from about 1 microliter to about 100 microliters. 2. The electrolytic eluent generating device of claim 1 , in which the dead volume is a sum of a first volume of the first generation chamber and a second volume of the second generation chamber. 3. The electrolytic eluent generating device of claim 1 , in which the first generant is a compound comprising an anion and a cation, the anion selected from the group consisting of a hydroxide, a carbonate, a phosphate, a sulfate, a trifluoroacetate, an acetate, a methanesulfonate, and a combination thereof, the cation selected from the group consisting of a hydronium, a potassium, a sodium, a lithium, an ammonium, and a combination thereof. 4. The electrolytic eluent generating device of claim 1 , in which the second generant is a compound comprising an anion and a cation, the anion selected from the group consisting of a hydroxide, a carbonate, a phosphate, a sulfate, a trifluoroacetate, an acetate, a methanesulfonate, and a combination thereof, the cation selected from the group consisting of a hydronium, a potassium, a sodium, a lithium, an ammonium, and a combination thereof. 5. The electrolytic eluent generating device of claim 1 , in which the first generant and the second generant do not share a common anion. 6. The electrolytic eluent generating device of claim 1 , in which the first ion exchange barrier and the second ion exchange barrier comprise a cation exchange membrane and an anion exchange membrane, respectively. 7. The electrolytic eluent generating device of claim 1 , in which the first electrode is an anode disposed in the first ion source reservoir and the second electrode is a cathode disposed in the first generation chamber. 8. The electrolytic eluent generating device of claim 1 , in which the third electrode is a cathode disposed in the second ion source reservoir and the fourth electrode is an anode disposed in the second generation chamber. 9. A method of generating a concentration gradient eluent flow, the method comprising: pumping a liquid into an electrolytic eluent generating device of claim 1 ; adding a first generant and a second generant to the liquid; injecting a liquid sample that includes an analyte into a chromatographic separation device; inputting the liquid that includes the first generant and the second generant to provide a concentration gradient eluent flow into the chromatographic separation device; separating the analyte from matrix components in the chromatographic separation device; and detecting the analyte with a detector. 10. An electrolytic eluent generating device configured to generate at least two different generants, in which the at least two different generants include a first generant and a second generant, where a first generant concentration and a second generant concentration are both controllable as a function of time, the electrolytic eluent generating device comprising; a) a first eluent generator configured to i) receive a liquid from a pump; ii) add the first generant to the liquid; and iii) output the liquid that includes the first generant, in which the first eluent generator comprises: iv) a first ion source reservoir including a source of cations or anions; v) a first generation chamber including an inlet configured to receive the liquid and an outlet configured to output the liquid that includes the first generant; vi) a first ion exchange barrier at least partly disposed between the first ion source reservoir and the first generation chamber; vii) a first electrode in electrical communication with the first ion source reservoir; and viii) a second electrode in electrical communication with the first generation chamber; and b) a second eluent generator configured to i) receive the liquid from the pump; ii) add the second generant to the liquid; and iii) output the liquid that includes the second generant, in which the second eluent generator comprises: iv) a second ion source reservoir including a source of cations or anions; v) a second generation chamber including an inlet configured to receive the liquid and an outlet configured to output the liquid that includes the second generant; vi) a second ion exchange barrier at least partly disposed between the second ion source reservoir and the second generation chamber; vii) a third electrode in electrical communication with the second ion source reservoir; and vii) a fourth electrode in electrical communication with the second generation chamber; and c) a fluid junction including a first inlet, a second inlet, and an outlet, where i) the first inlet is configured to receive the liquid from the first eluent generator; ii) the second inlet is configured to receive the liquid from the second eluent generator; and iii) the outlet is configured to flow a mixture of the first generant and the second generant, in which the first and second eluent generators together have a dead volume ranging from about 1 microliter to about 100 microliters. 11. The electrolytic eluent generating device of claim 10 , in which the dead volume is a sum of a first volume of the first generation chamber and a second volume of the second generation chamber. 12. The electrolytic eluent generating device of claim 10 , in which the first generant is a compound comprising an anion and a cation, the anion selected from the group consisting of a hydroxide, a carbonate, a phosphate, a sulfate, a trifluoroacetate, an acetate, a methanesulfonate, and a combination thereof, the cation selected fr