Liquid chromatography analyzer system with on-line analysis of eluting fractions

What is claimed is: 1. A chromatography analyzer system for analyzing a first sample fraction, the chromatography analyzer system comprising: a first MIR analyzer for spectrally analyzing the first sample fraction, the first MIR analyzer including (i) a first MIR flow cell that receives the flowing first sample fraction, the first MIR flow cell having a path length of less than one hundred micrometers, (ii) a first MIR laser source that directs a first MIR beam having a first center wavenumber that is changed over time at the first sample fraction flowing in the first MIR flow cell, wherein the first center wavenumber is tuned over a first MIR wavelength range while the first sample fraction is flowing the first MIR flow cell, wherein the first MIR wavelength range is at least five percent of a MIR range, and wherein the first center wavenumber is tuned over a time frame of less than one hundred milliseconds, and (iii) a first MIR detector that receives light from the first sample fraction in the first MIR flow cell and generates first MIR data of the first sample fraction for the first MIR wavelength range. 2. The chromatography analyzer system of claim 1 further comprising a second MIR analyzer for spectrally analyzing the first sample fraction while the first sample fraction is flowing in the second MIR analyzer, the second MIR analyzer including (i) a second MIR flow cell that receives the flowing first sample fraction, (ii) a second MIR laser source that directs a second MIR beam having a second center wavenumber that is rapidly changed over time in a second MIR wavelength range at the first sample fraction in the second MIR flow cell, and (iii) a second MIR detector that receives light from the first sample fraction in the second MIR flow cell and generates second MIR data of the first sample fraction for the second MIR wavelength range. 3. The chromatography analyzer system of claim 2 wherein the first MIR analyzer and the second MIR analyzer are arranged in series so that the first sample fraction flows from the first MIR flow cell to the second MIR flow cell. 4. The chromatography analyzer system of claim 3 further comprising a control and analysis system that uses the first MIR data and the second MIR data to estimate a time delay between when the first sample fraction flows from the first MIR flow cell to the second MIR flow cell. 5. The chromatography analyzer system of claim 2 further comprising a control and analysis system that uses the first MIR data and the second MIR data to generate a combined MIR data. 6. The chromatography analyzer system of claim 5 wherein the control and analysis system uses the combined MIR data to estimate a characteristic of the first sample fraction. 7. The chromatography analyzer system of claim 5 wherein the control and analysis system identifies a region of interest in the combined MIR data and generates combined MIR spectral data for the region of interest. 8. The chromatography analyzer system of claim 7 wherein the control and analysis system analyzes the combined MIR spectral data for the region of interest to chart chemical changes in a polydisperse sample as a function of elution time. 9. The chromatography analyzer system of claim 2 further comprising a non-MIR analyzer for spectrally analyzing the first sample fraction in a non-MIR range while the first sample fraction is flowing in the non-MIR analyzer, the non-MIR analyzer generating non-MIR data for the non-MIR range. 10. The chromatography analyzer system of claim 9 wherein the non-MIR analyzer, the first MIR analyzer and the second MIR analyzer are arranged in series so that the first sample fraction flows from the non-MIR analyzer to the first MIR flow cell and then to the second MIR flow cell. 11. The chromatography analyzer system of claim 9 further comprising a control and analysis system that uses the non-MIR data, the first MIR data and the second MIR data to estimate a characteristic of the first sample fraction. 12. The chromatography analyzer system of claim 9 further comprising a control and analysis system that uses the non-MIR data, the first MIR data and the second MIR data to estimate at least one of (i) delay times between analyzers, (ii) a volume of the first sample fraction, and (iii) a band broadening of the first sample fraction. 13. The chromatography analyzer system of claim 2 further comprising a third MIR analyzer for spectrally analyzing the first sample fraction while the first sample fraction is flowing in the third MIR analyzer, the third MIR analyzer including (i) a third MIR flow cell that receives the flowing first sample fraction, (ii) a third MIR laser source that directs a third MIR beam having a third center wavenumber that is rapidly changed over time in a third MIR wavelength range at the first sample fraction in the third MIR flow cell, and (iii) a third MIR detector that receives light from the first sample fraction in the third MIR flow cell and generates third MIR data of the first sample fraction for the third wavelength range; wherein the first MIR analyzer, the second MIR analyzer, and the third MIR analyzer are arranged in series so that the first sample fraction flows from the first MIR flow cell to the second MIR flow cell and then to the third MIR flow cell. 14. The chromatography analyzer system of claim 1 further comprising a fractionator that creates the first sample fraction from a sample flowing in the fractionator. 15. The chromatography analyzer system of claim 1 wherein the first MIR analyzer spectrally analyzes a second sample fraction while the second sample fraction is flowing in the first MIR analyzer, and the first MIR detector generates second MIR data of the second sample fraction for the first MIR wavelength range. 16. The chromatography analyzer system of claim 1 wherein the first MIR analyzer has a band broadening of less than twenty microliters. 17. The chromatography analyzer system of claim 1 wherein the first flow cell has a volume of less than ten microliters. 18. A method for analyzing a first sample fraction, the method comprising: directing the first sample fraction through a first MIR flow cell, the first MIR flow cell having a path length of less than one hundred micrometers; directing a first MIR beam having a first center wavenumber that is changed over time at the first sample fraction in the first MIR flow cell, wherein the first center wavenumber is tuned over a first MIR wavelength range while the first sample fraction is flowing the first MIR flow cell, wherein the first MIR wavelength range is at least five percent of a MIR range, and wherein the first center wavenumber is tuned over a time frame of less than one hundred milliseconds; and generating first MIR data of the first sample fraction for the first MIR wavelength range with a first MIR detector that receives light from the first sample fraction in the first MIR flow cell. 19. The method of claim 18 further comprising (i) directing the first sample fraction through a second MIR flow cell; (ii) directing a second MIR beam having a second center wavenumber that is rapidly changed over time in a second MIR wavelength range at the first sample fraction in the second MIR flow cell; and (iii) generating second MIR data of the first sample fraction for the second MIR wavelength range with a second MIR detector that receives light from the first sample fraction in the second MIR flow cell. 20. The method of claim 19 further comprising uses the first MIR data and the second MIR