Method and apparatus for scaling between chromatographic systems using highly compressible fluids

What is claimed is: 1 . A method for efficiently transferring a carbon dioxide based separation procedure from a reference chromatographic system to a field chromatographic system, the method comprising: (a) identifying an average system pressure, an average column pressure, and an elution time for at least one analyte in a carbon dioxide based separation in the reference chromatographic system; (b) modifying at least one characteristic of the tubing between a pump outlet and a column inlet or between a column outlet and a back pressure regulator inlet in the reference chromatographic system to create a modified reference chromatographic system; (c) identifying an average system pressure, an average column pressure, and an elution time for the at least one analyte in the carbon dioxide based separation in the modified reference chromatographic system; (d) calculating an elution time differential and a correction coefficient for the at least one analyte in the carbon dioxide based separation; and (e) identifying an average system pressure and an elution time for the at least one analyte in the carbon dioxide based separation in a field chromatographic system; and (f) calculating an average column pressure for the carbon dioxide based separation in the field chromatographic system as the product of an average system pressure and the correction factor, wherein the correction factor comprises a function of the elution time, the elution time differential, and the fitting coefficient for the at least one analyte in the carbon dioxide based separation. 2 . The method of claim 1 wherein the at least one analyte comprises a first analyte and a second analyte; wherein identifying an elution time for the at least one analyte in the carbon dioxide based separation comprises identifying a first elution time for the first analyte and a second elution time for the second analyte in the carbon dioxide based separation; and wherein calculating an elution time differential and a correction coefficient for the at least one analyte in the carbon dioxide based separation comprises calculating a first elution time differential and a first correction coefficient for the first analyte and calculating a second elution time differential and a second correction coefficient for the second analyte; and wherein the correction factor comprises a function of the first elution time, the first elution time differential, and the first fitting coefficient for the first analyte and of the second elution time, the second elution time differential, and the second fitting coefficient for the second analyte in the carbon dioxide based separation. 3 . The method of claim 1 wherein the at least one analyte comprises a first analyte, a second analyte, and a third analyte; wherein identifying an elution time for the at least one analyte in the carbon dioxide based separation comprises identifying a first elution time for the first analyte, a second elution time for the second analyte, and a third elution time for the third analyte in the carbon dioxide based separation; and wherein calculating an elution time differential and a correction coefficient for the at least one analyte in the carbon dioxide based separation comprises calculating a first elution time differential and a first correction coefficient for the first analyte, calculating a second elution time differential and a second correction coefficient for the second analyte, and calculating a third elution time differential and a third correction coefficient for the third analyte; and wherein the correction factor comprises a function of the first elution time, the first elution time differential, and the first fitting coefficient for the first analyte; of the second elution time, the second elution time differential, and the second fitting coefficient for the second analyte, and of the third elution time, the third elution time differential, and the third fitting coefficient for the third analyte in the carbon dioxide based separation. 4 . The method of claim 1 wherein modifying at least one characteristic of the tubing further comprises modifying at least one characteristic of the tubing between a pump outlet and a column inlet in the reference chromatographic system to create the modified reference chromatographic system; the method further comprising identifying an average system pressure, an average column pressure, and an elution time for the at least one analyte in the carbon dioxide based separation in the modified reference chromatographic system. 5 . The method of claim 1 wherein modifying at least one characteristic of the tubing further comprises modifying at least one characteristic of the tubing between a column outlet and a back pressure regulator inlet in the reference chromatographic system to create the modified reference chromatographic system; the method further comprising identifying an average system pressure, an average column pressure, and an elution time for the at least one analyte in the carbon dioxide based separation in the modified reference chromatographic system. 6 . The method of claim 1 wherein modifying at least one characteristic of the tubing further comprises modifying at least one characteristic of the tubing between a pump outlet and a column inlet in the reference chromatographic system to create a first modified reference chromatographic system; and modifying at least one characteristic of the tubing between a column outlet and a back pressure regulator inlet in the reference chromatographic system to create a second modified reference chromatographic system; the method further comprising identifying an average system pressure, an average column pressure, and an elution time for the at least one analyte in the carbon dioxide based separation in the first modified reference chromatographic system; and identifying an average system pressure, an average column pressure, and an elution time for the at least one analyte in the carbon dioxide based separation in the second modified reference chromatographic system. 7 . The method of claim 1 further comprising adjusting a pressure parameter in the carbon dioxide based separation in the field chromatographic system based on the calculated average column pressure. 8 . A method for efficiently transferring a carbon dioxide based separation procedure from a first chromatographic system to a second chromatographic system, the method comprising: (a) identifying a plurality of parameter values for use in a carbon dioxide based separation in the second chromatographic system, wherein the parameters associated with the plurality of parameter values comprise (1) a percentage of modifier, (2) a pump outlet pressure (3) a back pressure regulator pressure, (4) a temperature, and (5) a flow rate; (b) checking a lookup table for a tubing pressure drop associated with the plurality of parameter values, wherein the tubing pressure drop is a difference between a pressure measured near the location of the column in the first chromatographic system and either a pump outlet pressure or a back pressure regulator pressure; (c) applying the tubing pressure drop to the determine a column pressure for the carbon dioxide based separation procedure in the second chromatography system; and (d) adjusting one of the plurality of parameter values for use in a carbon dioxide based separation in the second chromatographic system to more closely match the average column pressure for the carbon dioxide based separation in the first chromatographic system. 9 . The method of claim 8 wherein the pressure measured near the location of the column in the first chromatographic system is measured with a pressure transducer in a zero