The aim of this study is to
determine the isotopic composition (¦Ä
18O and ¦Ä
2H) of interstitial water in bentonites. The study had been carried out from adsorbed vapour in homoionic bentonites. We have worked with the fraction <20 ¦Ìm of a bentonite from Serrata
de N¨ªjar (Almer¨ªa, Spain). Homoionic sodium and calcium bentonites were prepared as well as variable quantities of exchangeable Na/Ca (75Ca/25Na; 50Ca/50Na; 25Ca/75Na), by mixing pure sodium and calcium suspensions in the appropriate quantities. To carry out the hydration of the samples, every one of them was previously dried at 300 ¡ãC overnight, they were subjected to controlled saturation conditions in an atmosphere of different relative humidity and at a constant temperature of 20 ¡ãC, until equilibrium was achieved. The different vapour pressures were:
P/
Po = 0.05;
P/
Po = 0.078;
P/
Po = 0.15;
P/
Po = 0.32;
P/
Po = 0.45;
P/
Po = 0.63;
P/
Po = 0.8;
P/
Po = 1, obtained from the saturated solutions of different salts or sulphuric acid.
The saturation water was extracted for isotopic analysis from an aliquot of a saturated sample. The technique used was vacuum extraction based on a modification of the one described by .
The differentiation between the isotopes of 18O and 2H from interstitial water in the bentonite samples, depending on the different relative humidity, may affect the ions diffusion in the interstitial solutions, since in those from low relative humidities, there could be a higher diffusion velocity as they are formed by molecules of light isotopes, versus interstitial solutions from higher relative humidities or those near saturation. This fact should be taken into account in studies on cation and solute transport from these solutions inside bentonite, even though it is important to continue studying and corroborating it with a larger number of solutions isotopically marked.