초록 ▼

A more efficient method for combustion or oxidation of samples containing nitrogen, phosphorus and/or sulfur to their corresponding oxides is disclosed, where method uses multi-staged addition of an oxidizing agent to enhance oxidation and liberation of nitrogen, phosphorus and/or sulfur oxides for

A more efficient method for combustion or oxidation of samples containing nitrogen, phosphorus and/or sulfur to their corresponding oxides is disclosed, where method uses multi-staged addition of an oxidizing agent to enhance oxidation and liberation of nitrogen, phosphorus and/or sulfur oxides for subsequent detection. The method of the present invention allows for the injection of larger samples or the introduction of a greater amount of sample per unit of time which results in a larger amount of analyte being delivered to the detector per unit of time, thereby improving detection limits and detection efficiency.

대표청구항 ▼

What is claimed is: 1. A method for oxidizing samples comprising the steps of: introducing a sample and a first amount of an oxidizing agent into an oxidation chamber maintained at an elevated temperature, and introducing at least one additional amount of the oxidizing agent into the combustion ch

What is claimed is: 1. A method for oxidizing samples comprising the steps of: introducing a sample and a first amount of an oxidizing agent into an oxidation chamber maintained at an elevated temperature, and introducing at least one additional amount of the oxidizing agent into the combustion chamber, where the combustion chamber comprises an inner tube having an interior and an exterior and an outer tube having an interior, where the first amount of oxidizing agent oxidizes the sample in a first combustion zone, which comprises the interior of the inner tube and the at least one additional amount of the oxidizing agent continues to oxidize the sample in a second combustion zone, which comprises a region between the exterior of the inner tube and the interior of the outer tube, where the first and additional amounts of the oxidizing agent are in excess of a stoichiometric amount of oxidizing agent needed to completely convert all oxidizable components in the sample into their corresponding oxides, where the oxidizable components are partially or completely convened into their corresponding oxides, and where the introduction the additional amounts of oxidizing agent improves an oxidation efficiency of the combustion chamber. 2. The method of claim 1, further comprising the step of: atomizing or nebulizing the sample and the first amount of the oxidizing agent prior to the first introducing step in an atomizer or nebulizer. 3. The method of claim 1, further comprising the steps of: atomizing or nebulizing the sample and the first amount of the oxidizing agent prior to the first introducing step in an atomizer or nebulizer; forwarding the oxides to at least one species specific detector; and detecting at least one oxide of nitrogen, phosphorus and/or sulfur in the at least one species specific detector. 4. The method of claim 1, further comprising the steps of: separating the sample into its components in a separation apparatus; atomizing or nebulizing each sample component and the first amount of the oxidizing agent prior to the first introducing step in an atomizer or nebulizer; forwarding the oxides to at least one species specific detector; and detecting at least one oxide of nitrogen, phosphorus and/or sulfur in the at least one species specific detector. 5. The method of claim 1, further comprising the steps of: atomizing or nebulizing the sample and the first amount of the oxidizing agent prior to the first introducing step in an atomizer or nebulizer; transforming at least one oxide of sulfur to a sulfur species capable of undergoing ozone induced chemiluminescence; forwarding the oxides and the sulfur species to at least one species specific detector; and detecting at least one oxide of nitrogen, phosphorus and/or sulfur in the at least one species specific detector. 6. The method of claim 1, further comprising the steps of: separating the sample into its components in a separation apparatus; atomizing or nebulizing each sample component and the first amount of the oxidizing agent prior to the first introducing step in an atomizer or nebulizer; transforming at least one oxide of sulfur to a sulfur species capable of undergoing ozone induced chemiluminescence after the second introducing step; forwarding the oxides and the sulfur species to at least one species specific detector; and detecting at least one oxide of nitrogen, phosphorus and/or sulfur in the at least one species specific detector. 7. The method of claim 1, wherein the introduction of the first and at least one additional amounts of oxidizing agent improves liberation of nitrogen, phosphorus and/or sulfur from sample components containing nitrogen, phosphorus and/or sulfur and improves the detection of oxides of nitrogen, phosphorus and/or sulfur. 8. The method of claim 1, wherein a flow rate of the first amount of the oxidizing agent is between about 50 cc/min and about 1000 cc/min and a flow rate of the at least one additional amount of the oxidizing agent is between about 10 cc/min and about 300 cc/min. 9. The method of claim 1, wherein the elevated temperature is between about 300째 and about 1600째 C. and. 10. The method of claim 1, wherein the sample is introduced at a volume of from about 1 μL to 200 μL at a sample introduction rate of about 0.5 μL/sec to about 6 μL/sec. 11. A method for oxidizing samples comprising the steps of: introducing a sample and a first amount of an oxidizing agent into an oxidation chamber maintained at an elevated temperature, and introducing at least one additional amount of the oxidizing agent into the combustion chamber, where the combustion chamber comprises a U-shaped combustion tube and where the at least one additional amount of the oxidizing agent is introduced into the U-shaped combustion tube at about a turn in the U-shaped combustion tube, where the first and additional amounts of the oxidizing a gent are in excess of a stoichiometric a mount of oxidizing agent needed to completely convert all oxidizable components in the sample into their corresponding oxides, where the oxidizable components are partially or completely converted into their corresponding oxides, and where the introduction of the first and additional amounts of oxidizing agent improves an oxidation efficiency of the combustion chamber. 12. The method of claim 11, further comprising the step of: atomizing or nebulizing the sample and the first amount of the oxidizing agent prior to the first introducing step in an atomizer or nebulizer. 13. The method of claim 11, further comprising the steps of: atomizing or nebulizing the sample and the first amount of the oxidizing agent prior to the first introducing step in an atomizer or nebulizer; forwarding the oxides to at least one species specific detector; and detecting at least one oxide of nitrogen, phosphorus and/or sulfur in the at least one species specific detector. 14. The method of claim 11, further comprising the steps of: separating the sample into its components in a separation apparatus; atomizing or nebulizing each sample component and the first amount of the oxidizing agent prior to the first introducing step in an atomizer or nebulizer; forwarding the oxides to at least one species specific detector; and detecting at least one oxide of nitrogen, phosphorus and/or sulfur in the at least one species specific detector. 15. The method of claim 11, further comprising the steps of: atomizing or nebulizing the sample and the first amount of the oxidizing agent prior to the first introducing step in an atomizer or nebulizer; transforming at least one oxide of sulfur to a sulfur species capable of undergoing ozone induced chemiluminescence; forwarding the oxides and the sulfur species to at least one species specific detector; and detecting at least one oxide of nitrogen, phosphorus and/or sulfur in the at least one species specific detector. 16. The method of claim 11, further comprising the steps of: separating the sample into its components in a separation apparatus; atomizing or nebulizing each sample component and the first amount of the oxidizing agent prior to the first introducing step in an atomizer or nebulizer; transforming at least one oxide of sulfur to a sulfur species capable of undergoing ozone induced chemiluminescence after the second introducing step; forwarding the oxides and the sulfur species to at least one species specific detector; and detecting at least one oxide of nitrogen, phosphorus and/or sulfur in the at least one species specific detector. 17. The method of claim 11, wherein the introduction of the first and at least one additional amounts of oxidizing agent improves liberation of nitrogen, phosphorus and/or sulfur form sample components containing nitrogen, phosphorus and/or sulfur and improves the detection of oxides of nitrogen, phosphorus and/or sulfur. 18. The method of claim 11, wherein a flow rate of the first amount of the oxidizing agent is between about 50 cc/min and about 1000 cc/min and a flow rate of the at least one additional amount of the oxidizing agent is between about 10 cc/min and about 300 cc/min. 19. The method of claim 11, wherein the elevated temperature is between about 300째 and about 1600째 C. 20. The method of claim 11, wherein a sample is introduced at a volume of from about 1 μL to 200 μL at a sample introduction rate of about 0.5 μL/sec to about 6 μL/sec. 21. A method for oxidizing samples comprising: mixing a sample with a first amount of an oxidizing agent to form an oxidizing mixture; introducing the oxidizing mixture into a first combustion zone of a combustion chamber; converting a portion of oxidizable components of the sample into their corresponding oxides; introducing a second amount of the oxidizing agent into a second combustion zone of the combustion chamber; partially or completely converting all oxidizable components of the sample into their corresponding oxides, where the combustion chamber comprises an inner tube having an interior and an exterior and an outer tube having an interior, where the first amount of oxidizing agent oxidizes the sample in a first combustion zone, which comprises the interior of the inner tube and the at least one additional amount of the oxidizing agent continues to oxidize the sample in a second combustion zone, which comprises a region between the exterior of the inner tube and the interior of the outer tube, where the first and additional amounts of the oxidizing agent are in excess of a stoichiometric amount of oxidizing agent needed to completely convert all oxidizable components in the sample into their corresponding oxides, where the oxidizable components are partially or completely converted into their corresponding oxides, and where the introduction of the first and additional amounts of oxidizing agent improves an oxidation efficiency of the combustion chamber. 22. The method of claim 21, further comprising the step of: atomizing or nebulizing the oxidizing mixture prior to the first introducing step in an atomizer or nebulizer. 23. The method of claim 21, further comprising the steps of: atomizing or nebulizing the oxidizing mixture prior to the first introducing step in an atomizer or nebulizer; forwarding the oxides to at least one species specific detector; and detecting at least one oxide of nitrogen, phosphorus and/or sulfur in the at least one species specific detector. 24. The method of claim 21, further comprising the steps of: separating the sample into its components in a separation apparatus; mixing and atomizing or nebulizing each sample component and the first amount of the oxidizing agent to form the oxidizing mixture prior to the first introducing step in an atomizer or nebulizer; forwarding the oxides to at least one species specific detector; and detecting at least one oxide of nitrogen, phosphorus and/or sulfur in the at least one species specific detector. 25. The method of claim 21, further comprising the steps of: atomizing or nebulizing the oxidizing mixture prior to the first introducing step in an atomizer or nebulizer; transforming at least one oxide of sulfur to a sulfur species capable of undergoing ozone induced chemiluminescence; forwarding the oxides and the sulfur species to at least one species specific detector; and detecting at least one oxide of nitrogen, phosphorus and/or sulfur in the at least one species specific detector. 26. The method of claim 21, further comprising the steps of: separating the sample into its components in a separation apparatus; mixing and atomizing or nebulizing each sample component and the first amount of the oxidizing agent to from the oxidizing mixture prior to the first introducing step in an atomizer or nebulizer; transforming at least one oxide of sulfur to a sulfur species capable of undergoing ozone induced chemiluminescence after the second introducing step; forwarding the oxides and the sulfur species to at least one species specific detector; and detecting at least one oxide of nitrogen, phosphorus and/or sulfur in the at least one species specific detector. 27. The method of claim 21, wherein the introduction of the first and at least one additional amounts of oxidizing agent improves liberation of nitrogen, phosphorus and/or sulfur form sample components containing nitrogen, phosphorus and/or sulfur and improves the detection of oxides of nitrogen, phosphorus and/or sulfur. 28. The method of claim 21, wherein a flow rate of the first amount of the oxidizing agent is between about 50 cc/min and about 1000 cc/min and a flow rate of the at least one additional amount of the oxidizing agent is between about 10 cc/min and about 300 cc/min. 29. The method of claim 21, wherein the elevated temperature is between about 300째 and about 1600째 C. 30. The method of claim 21, wherein a sample is introduced at a volume of from about 1 μL to 200 μL at a sample introduction rate of about 0.5 μL/sec to about 6 μL/sec. 31. A method for oxidizing samples comprising: mixing a sample with a first amount of an oxidizing agent to form an oxidizing mixture; introducing the oxidizing mixture into a first combustion zone of a combustion chamber; converting a portion of oxidizable components of the sample into their corresponding oxides; introducing a second amount of the oxidizing agent into a second combustion zone of the combustion chamber; partially or completely converting all oxidizable components of the sample into their corresponding oxides, where the combustion chamber comprises a U-shaped combustion tube and where the at least one additional amount of the oxidizing agent is introduced into the U-shaped combustion tube at about a turn in the U-shaped combustion tube, where the first and additional a mounts of the oxidizing agent are in excess of a stoichiometric a mount of oxidizing agent needed to completely convert all oxidizable components in the sample into their corresponding oxides, the oxidizable components are partially or completely converted into their corresponding oxides, and where the introduction of the first and additional amounts of oxidizing agent improves an oxidation efficiency of the combustion chamber. 32. The method of claim 31, further comprising the step of: atomizing or nebulizing the oxidizing mixture prior to the first introducing step in an atomizer or nebulizer. 33. The method of claim 31, further comprising the steps of: atomizing or nebulizing the oxidizing mixture prior to the first introducing step in an atomizer or nebulizer; forwarding the oxides to at least one species specific detector; and detecting at least one oxide of nitrogen, phosphorus and/or sulfur in the at least one species specific detector. 34. The method of claim 31, further comprising the steps of: separating the sample into its components in a separation apparatus; mixing and atomizing or nebulizing each sample component and the first amount of the oxidizing agent to form the oxidizing mixture prior to the first introducing step in an atomizer or nebulizer; forwarding the oxides to at least one species specific detector; and detecting at least one oxide of nitrogen, phosphorus and/or sulfur in the at least one species specific detector. 35. The method of claim 31, further comprising the steps of: atomizing or nebulizing the oxidizing mixture prior to the first introducing step in an atomizer or nebulizer; transforming at least one oxide of sulfur to a sulfur species capable of undergoing ozone induced chemiluminescence; forwarding the oxides and the sulfur species to at least one species specific detector; and detecting at least one oxide of nitrogen, phosphorus and/or sulfur in the at least one species specific detector. 36. The method of claim 31, further comprising the steps of: separating the sample into its components in a separation apparatus; mixing and atomizing or nebulizing each sample component and the first amount of the oxidizing agent to from the oxidizing mixture prior to the first introducing step in an atomizer or nebulizer; transforming at least one oxide of sulfur to a sulfur species capable of undergoing ozone induced chemiluminescence after the second introducing step; forwarding the oxides and the sulfur species to at least one species specific detector; and detecting at least one oxide of nitrogen, phosphorus and/or sulfur in the at least one species specific detector. 37. The method of claim 31, wherein the introduction of the first and at least one additional amounts of oxidizing agent improves liberation of nitrogen, phosphorus and/or sulfur form sample components containing nitrogen, phosphorus and/or sulfur and improves the detection of oxides of nitrogen, phosphorus and/or sulfur. 38. The method of claim 31, wherein a flow rate of the first amount of the oxidizing agent is between about 50 cc/min and about 1000 cc/min and a flow rate of the at least one additional amount of the oxidizing agent is between about 10 cc/min and about 300 cc/min. 39. The method of claim 31, wherein the elevated temperature is between about 300째 and about 1600째 C. 40. The method of claim 31, wherein a sample is introduced at a volume of from about 1 μL to 200 μL at a sample introduction rate of about 0.5 μL/sec to about 6 μL/sec. 41. A method for oxidizing samples comprising: separating a sample into its components in a separation apparatus; mixing each component with a first amount of an oxidizing agent; introducing each component and a first amount of the oxidizing agent into a combustion chamber maintained at an elevated temperature; converting a portion of oxidizable components of the sample into their corresponding oxides; introducing at least one additional amount of the oxidizing agent; and partially or completely converting each component of the sample into its corresponding oxides, where the combustion chamber comprises an inner tube having an interior and an exterior and an outer tube having an interior, where the first amount of oxidizing agent oxidizes the sample in a first combustion zone, which comprises the interior of the inner tube and the at least one additional amount of the oxidizing agent continues to oxidize the sample in a second combustion zone, which comprises a region between the exterior of the inner tube and the interior of the outer tube, where the first and additional amounts of the oxidizing agent are in excess of a stoichiometric amount of oxidizing agent needed to completely convert all oxidizable components in the sample into their corresponding oxides, where the oxidizable components are partially or completely converted into their corresponding oxides, and where the introduction of the first and additional amounts of oxidizing agent improves an oxidation efficiency of the combustion chamber. 42. The method of claim 41, further comprising the step of: atomizing or nebulizing the oxidizing mixture prior to the first introducing step in an atomizer or nebulizer. 43. The method of claim 41, further comprising the steps of: atomizing or nebulizing the oxidizing mixture prior to the first introducing step in an atomizer or nebulizer; forwarding the oxides to at least one species specific detector; and detecting at least one oxide of nitrogen, phosphorus and/or sulfur in the at least one species specific detector. 44. The method of claim 41, further comprising the steps of: atomizing or nebulizing the oxidizing mixture prior to the first introducing step in an atomizer or nebulizer; transforming at least one oxide of sulfur to a sulfur species capable of undergoing ozone induced chemiluminescence; forwarding the oxides and the sulfur species to at least one species specific detector; and detecting at least one oxide of nitrogen, phosphorus and/or sulfur in the at least one species specific detector. 45. The method of claim 41, wherein the introduction of the first and at least one additional amounts of oxidizing agent improves liberation of nitrogen, phosphorus and/or sulfur form sample components containing nitrogen, phosphorus and/or sulfur and improves the detection of oxides of nitrogen, phosphorus and/or sulfur. 46. The method of claim 41, wherein a flow rate of the first amount of the oxidizing agent is between about 50 cc/min and about 1000 cc/min and a flow rate of the at least one additional amount of the oxidizing agent is between about 10 cc/min and about 300 cc/min. 47. The method of claim 41, wherein the elevated temperature is between about 300째 and about 1600째 C. 48. The method of claim 41, wherein a sample is introduced at a volume of from about 1 μL to 200 μL at a sample introduction rate of about 0.5 μL/sec to about 6 μL/sec. 49. A method for oxidizing samples comprising: separating a sample into its components in a separation apparatus; mixing each component with a first amount of an oxidizing agent; introducing each component and a first amount of the oxidizing agent into a combustion chamber maintained at an elevated temperature; converting a portion of oxidizable components of the sample into their corresponding oxides; introducing at least one additional amount of the oxidizing agent; and partially or completely converting each component of the sample into its corresponding oxides, where the combustion chamber comprises a U-shaped combustion tube and where the at least one additional amount of the oxidizing agent is introduced into the U-shaped combustion tube at about a turn in the U-shaped combustion tube, where the first and additional a mounts of the oxidizing agent are in excess of a stoichiometric a mount of oxidizing agent needed to completely convert all oxidizable components in the sample into their corresponding oxides, where the oxidizable components are partially or completely converted into their corresponding oxides, and where the introduction of the first and additional amounts of oxidizing agent improves an oxidation efficiency of the combustion chamber. 50. The method of claim 49, further comprising the step of: atomizing or nebulizing the oxidizing mixture prior to the first introducing step in an atomizer or nebulizer. 51. The method of claim 49, further comprising the steps of: atomizing or nebulizing the oxidizing mixture prior to the first introducing step in an atomizer or nebulizer; forwarding the oxides to at least one species specific detector; and detecting at least one oxide of nitrogen, phosphorus and/or sulfur in the at least one species specific detector. 52. The method of claim 49, further comprising the steps of: atomizing or nebulizing the oxidizing mixture prior to the first introducing step in an atomizer or nebulizer; transforming at least one oxide of sulfur to a sulfur species capable of undergoing ozone induced chemiluminescence; forwarding the oxides and the sulfur species to at least one species specific detector; and detecting at least one oxide of nitrogen, phosphorus and/or sulfur in the at least one species specific detector. 53. The method of claim 49, wherein the introduction of the first and at least one additional amounts of oxidizing agent improves liberation of nitrogen, phosphorus and/or sulfur form sample components containing nitrogen, phosphorus and/or sulfur and improves the detection of oxides of nitrogen, phosphorus and/or sulfur. 54. The method of claim 49, wherein a flow rate of the first amount of the oxidizing agent is between about 50 cc/min and about 1000 cc/min and a flow rate of the at least one additional amount of the oxidizing agent is between about 10 cc/min and about 300 cc/min. 55. The method of claim 49, wherein the elevated temperature is between about 300째 and about 1600째 C. 56. The method of claim 49, wherein a sample is introduced at a volume of from about 1 μL to 200 μL at a sample introduction rate of about 0.5 μL/sec to about 6 μL/sec.