Capillary ion chromatography

What is claimed is: 1. An electrolytically-regenerated suppressor for capillary ion chromatography comprising: (a) a central chamber including: (i) an ion exchange packing; and (ii) a capillary tubing having an inlet and an outlet and formed of a permselective ion exchange membrane, the capillary tubing being at least partially disposed in the ion exchange packing; (b) a first electrode chamber having an inlet and an outlet, the first electrode chamber including: (i) a first electrode: (ii) a first permselective barrier that separates the first electrode chamber from the ion exchange packing; and (c) a second electrode chamber having an inlet and an outlet, the second electrode chamber including: (i) a second electrode; (ii) a second permselective barrier that separates the second electrode chamber from the ion exchange packing. 2. The suppressor of claim 1 further comprising: (d) a source of flowing an aqueous regenerant liquid in fluid communication with an inlet of the central chamber. 3. The suppressor of claim 1 , in which an outlet of the central chamber is in fluid communication with the first electrode chamber inlet. 4. The suppressor of claim 1 , in which the first electrode chamber outlet is in fluid communication with the second electrode chamber inlet. 5. The suppressor of claim 1 , in which the ion exchange packing includes substrates with exchangeable ions comprising weakly acidic or weakly basic functional groups. 6. The suppressor of claim 1 , in which an outer wall of the capillary tubing comprises exchangeable ions comprising a weakly acidic or a weakly basic functional groups. 7. The suppressor of claim 6 , in which an inner wall of the capillary tubing comprises exchangeable ions comprising a strongly acidic or a strongly basic functional groups. 8. The suppressor of claim 6 , in which the weakly acidic or the weakly basic functional groups comprise moieties on polymers grafted to the outer wall of the tubing. 9. The suppressor of claim 1 , in which the packing is selected to have an ion exchange capacity from at least about 10 to 100,000 times more than the ion exchange capacity of the capillary tubing. 10. The suppressor of claim 1 , in which the capillary tubing has a diameter ranging from about 5 to 1000 microns. 11. The suppressor of claim 1 , in which the capillary tubing has a diameter ranging from about 200 to 600 microns. 12. An ion chromatography system comprising: (a) an electrolytic suppressor of claim 1 ; and (b) a capillary chromatography column in fluid communication with the capillary tubing inlet. 13. The system of claim 12 further comprising: (c) a detector in fluid communication with the capillary tubing outlet. 14. A method for suppressing ions in capillary chromatography, the method comprising: flowing an aqueous sample stream including separated sample ionic species of one charge, positive or negative, in an eluent, through a capillary tubing, the capillary tubing being formed of a permselective ion exchange membrane and at least partially disposed in an ion exchange packing; transporting counterions in the eluent of opposite charge to the sample ionic species across the tubing from an inner tubing wall to an outer tubing wall; flowing an aqueous regenerant liquid through the ion exchange packing past the outside of the tubing and to a first electrode chamber, the first electrode chamber including: a first electrode and a first permselective barrier that separates the first electrode chamber from the ion exchange packing; and flowing the aqueous regenerant liquid from the first electrode chamber to a second electrode chamber, the second electrode chamber including: a second electrode and a second permselective barrier that separates the second electrode chamber from the ion exchange packing. 15. The method of claim 14 , in which the sample ionic species includes an anionic species, the first electrode is an anode and the second electrode is a cathode, the method further comprising: generating hydronium ions at the anode; and converting the ion exchange packing to a hydronium form with the generated hydronium ions. 16. The method of claim 14 , in which the sample ionic species includes a cationic species, the first electrode is a cathode and the second electrode is an anode, the method further comprising: generating hydroxide ions at the cathode; and converting the ion exchange packing to a hydroxide form with the generated hydroxide ions. 17. A method for suppressing ions in capillary chromatography, the method comprising: flowing an aqueous sample stream including separated sample ionic species of one charge, positive or negative, in an eluent, through a capillary tubing, the capillary tubing being formed of a permselective ion exchange membrane and at least partially disposed in an ion exchange packing; transporting counterions in the eluent of opposite charge to the sample ionic species across the tubing from an inner tubing wall to an outer tubing wall; exchanging the transported counterions with ions on the ion exchange packing immediately adjacent to the outer tubing wall; flowing an aqueous regenerant liquid to a first electrode chamber, the first electrode chamber including: a first electrode and a first permselective barrier that separates the first electrode chamber from the ion exchange packing; and flowing the aqueous regenerant liquid from the first electrode chamber to a second electrode chamber, the second electrode chamber including: a second electrode and a second permselective barrier that separates the second electrode chamber from the ion exchange packing. 18. The method of claim 17 , in which the sample ionic species includes an anionic species, the method further comprising: intermittently regenerating the ion exchange packing by generating hydronium ions at the first electrode. 19. The method of claim 17 , in which the sample ionic species includes a cationic species, the method further comprising: intermittently regenerating the ion exchange packing by generating hydroxide ions at the first electrode.