Open AccessPhysical parameters in high-accuracy spectrophotometry
Author(s) -
Klaus D. Mielenz
Publication year - 1972
Publication title -
journal of research of the national bureau of standards. section a. physics and chemistry
Language(s) - Uncategorized
Resource type - Journals
eISSN - 2376-5704
pISSN - 0022-4332
DOI - 10.6028/jres.076a.040
Subject(s) - optics , monochromator , transmittance , stray light , collimated light , detector , linearity , interference (communication) , lens (geology) , ray , aperture (computer memory) , wavelength , sample (material) , accuracy and precision , physics , materials science , laser , computer science , computer network , channel (broadcasting) , quantum mechanics , acoustics , thermodynamics
The measured apparent transmittance T A of a filter or liquid sample depends on the beam geometry in the spectrophotometer. For focused light incident upon the sample, T A is different for systems having different f-numbers, and also depends on the state of polarization of the light. These effects are eliminated when the incident light is collimated; in this case T A approaches the "true" transmittance τ of the sample. Both modes of operation suffer from stray light and interference effects. The former may be reduced significantly by using mirror rather than lens optics, and the latter by suitable choice of the monochromator slit width. A new spectrophotometer based upon the above-mentioned design principles is described. The photometric precision of this instrument is shot-noise limited, permitting measurements to better than 10 -4 transmittance units. The double-aperture method of testing detector linearity to this level of precision is discussed. The conventional method of finding the nonlinearity correction can be replaced by a curve-fitting procedure giving better precision. Data on detector nonlinearity, and its dependence on wavelength, are presented.