Agilent Technologies 1260 User Manual page 127

6
How to optimize the Detector
Optimizing for Sensitivity, Selectivity, Linearity and Dispersion
Figure 57 Influence of the Slit Width on Baseline Noise
However, with a wider slit, the spectrograph's optical resolution (its ability to
distinguish between different wavelengths) diminishes. Any photodiode
receives light within a range of wavelength determined by the slit width. This
explains why the fine spectral structure of benzene disappears when using a
16-nm wide slit.
Furthermore, the absorbance is no longer strictly linear with concentration
for wavelengths at a steep slope of a compound's spectrum.
Substances with fine structures and steep slopes like benzene are very rare.
In most cases the width of absorbance bands in the spectrum is more like
30 nm as with anisic acid (Figure 53 on page 124).
In most situations, a slit width of 4 nm will give the best results.
Use a narrow slit (1 or 2 nm) if you want to identify compounds with fine
spectral structures or if you need to quantify at high concentrations
(> 1000 mAU) with a wavelength at the slope of the spectrum. Signals with a
wide bandwidth can be used to reduce baseline noise. Because (digital)
bandwidth is computed as average of absorbance, there is no impact on
linearity.
Use a wide (8 or 16 nm) slit when your sample contains very small
concentrations. Always use signals with bandwidth at least as wide as the slit
width.
Agilent 1260 Infinity DAD and MWD User Manual 127