Charge Compensation in Solid Solutions

Ϫ1 , rather than unity (which would Ca (1؊x) Gd (x) TiO 3 samples prepared by sintering in air at be the value if charge compensation occurred by reduction 1550؇C exhibit a primary perovskite-structured solid solution of Ti 4ϩ to Ti 3ϩ ), so precise chemical analysis of the Gdfor x up to about 0.2.

Charging processes on the bulk oxides and occurring during Auger Electron Spectroscopy Al 2 O 3 , ZrO 2 SiO 2 (AES) are studied. All samples experience a negative charge-up under the following parameters : electron beam energy > 1 keV, current density > 10-2 A cm-2 and di †erent angles of incidence.

Throughout the evolution of XPS, the ability to compensate for surface charging and accurately calibrate the binding energy scale, particularly with electrically inhomogeneous samples, has remained one of the most intractable problems. The last decade, however, has seen some quite significant advanc

There is an interaction energ? between solute atoms and a free crystal surface causing surface segregation. Size and shape of the interaction potential is estimated and the kinetics of the segregation process are discussed. R&m&-Lne cnergie d'interaction entre les atomes du sol& et la surface librc