Friday, September 30, 2011

UV / VIS, VWD, DAD, PDA HPLC DETECTOR SIGNAL BANDWIDTH (bw) SELECTION

Modern chromatography UV/VIS detectors offer the operator a choice of one to several hundred different signal wavelength choices (as is the case for Diode Array Detectors). Besides being able to specify a single wavelength, you can often choose a signal BANDWIDTH (bw) to associate with each wavelength [e.g. for a 280 nm signal with 10 nm bandwidth. This is often written as: 280 (10) or [280:10]. In many detectors, Signal Bandwidth is a variable, not fixed and represents the total number of nanometers across the specified signal value chosen. For example: If you select a signal wavelength of 280 nm and choose a bandwidth value of 10 nm, then you are actually gathering all signal data between 275 nm and 285 nm (5 nm to the left of the apex and 5 nm to the right for a total of 10 nm). Using a narrow bandwidth has the advantage of increasing the signal selectivity of the detector as you are only collecting data within a tight window. If you were to increase the bandwidth to 60 nm in the same example you would now be collecting data between 250 nm and 310 nm. The additional data collected over this wider range may reduce the total noise (by averaging it over a wide range), improve the S/N ratio (which may increase sensitivity), but it also reduces the selectivity. Large bandwidths also increase the chance you may include peak signal data from other co-eluting components into your signal data. You must select a bandwidth range for each signal wavelength which is located 'safely' away from any other potentially interfering peak. As with many things in life, balance is important. In this case, bandwidth choice is the balance between selectivity and sensitivity.


  • When developing new methods we recommend that you choose an initial bandwidth value of 10 nm for each signal. This provides a nice balance between selectivity and sensitivity. It is also a common bandwidth value used on many older UV/VIS detectors which have a fixed signal bandwidth (such as many single or variable wavelength detectors).


  • If you have determined the exact signal maximum for your sample and you would like to gain additional sensitivity for your sample (and thus decrease selectivity), re-run the analysis using several different, but increasing signal bandwidth values (e.g. 10, 20, 30, 50 and 100 nm). Choose bw values that are safely within the range of the detector, within the limits of the mobile phase's absorption region and also away from any potential co-eluting peaks. *To confirm which value is best, be sure and calculate the actual measured signal to noise ratio of the peak of interest after each analysis. This is a critical step! Do not be fooled by increases in the peak height or area alone as these changes are not always synonymous with better signal to noise ratios. Only by measuring the actual baseline noise level for each run and comparing it with the actual peak signal obtained will you be able to determine if increasing the bandwidth has provided you with better noise reduction and signal strength.


  • To increase spectral signal selectivity choose a bw value that is very narrow. A value such as 2 or 4 nm would allow the detector to collect only signal data that is at or near the apex of your selected wavelength. This can be very useful when trying to discriminate your signal from nearby signal peaks, especially at low wavelengths such as 210 nm.


  • When reporting your method conditions always include the wavelength AND bandwidth used for each signal. In order to accurately reproduce your method, this information is needed. *The flow cell dimensions, wavelength and bandwidth should always be included in your method.

10 comments:

  1. Nice post., keep it up. now i'm understand bandwidth & wavelength

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  2. Great article. I was wondering if you have thought about doing an article on charged aerosol detection since they are sometimes being used in conjunction with UV/Vis.

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    1. Thank you.

      As a matter of fact I have already written an article on two popular types of the evaporative detectors, the E.L.S.D and CAD several weeks ago. It is scheduled to appear here on my blog in the near future.

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    2. Update: "Evaporative HPLC Detectors; CAD (Charged Aerosol Detector) and ELSD (Evaporative Light-Scattering Detector)";
      https://hplctips.blogspot.com/2017/12/evaporative-hplc-detectors-cad-charged.html

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  3. Thanks for taking the time to write this article, very informative and useful

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  4. thanks! this information is very useful.

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  5. Great article! If there is no option to turn off the reference wavelength what is the recommended refence wavelength in your opinion? I am using Perkin Elmer Chromera software, and it seems like there is not an option to turn it off. Thank you

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    1. There is an option to turn OFF the 'Reference Wavelength" feature. In fact, if the software was well written (never assume this to be true), the default should always be 'OFF'. Without such an option, the detector may collect invalid data all of the time. *I recommend Training classes in the use of the CDS software as they are valuable and should be considered to get an overview of useful features.

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