Abstract

To deal with these problems investigators usually rely on a calibration method that makes use of a substance with an accurately known set of interatomic distances. The procedure consists of carrying out a diffraction experiment on the chosen calibrating substance, determining the value of the distances with use of the nominal (meter) value of the voltage, and then correcting the nominal voltage by an amount that produces the distances in the calibration substance. Examples of gases that have been used for calibration are carbon dioxide, carbon tetrachloride, carbon disulfide, and benzene; solids such as zinc oxide smoke (powder) deposited on a screen or slit have also been used. The question implied by the use of any standard molecule is, how accurate are the interatomic distance values assigned to the standard? For example, a solid calibrant is subject to heating by the electron beam, possibly producing unknown changes in the lattice constants, and polyatomic gaseous molecules require corrections for vibrational averaging ("shrinkage") effects that are uncertain at best. It has lately been necessary for us to investigate this matter in connection with on-going studies of several molecules in which size is the most important issue. These studies indicated that our usual method for retrieval of data captured on film needed improvement. The following is an account of these two issues - the accuracy of the distances assigned to the chosen standard molecule, and the improvements in our methods of retrieving the scattered intensity data.