Resolution limits for infrared microspectroscopy explored with synchrotron radiation

The spatial resolution for infrared microspectroscopy is investigated to determine the practical limits imposed by diffraction or optical aberrations. Quantitative results are obtained using high brightness synchrotron radiation, which serves as a diffraction-limited infrared "point source" for the microscope. The measured resolving power is in good agreement with diffraction theory, including a similar to 30% improvement for a confocal optical arrangement. The diffraction calculation also shows how the confocal setup leads to better image contrast. The full width at half maximum of the instrument's resolution pattern is approximately lambda /2 for this arrangement. One achieves this diffraction limit when the instrument's apertures define a region having dimensions equal to the wavelength of interest. While commercial microspectrometers are well corrected for optical aberrations (allowing diffraction-limited results), the standard substrates used for supporting specimens introduce chromatic aberrations. An analysis of this aberration is also presented, and correction methods described. (C) 2001 American Institute of Physics.