A simple electrical set-up to detect phase transitions is proposed and applied to a series of investigated samples: Gd, Cr, TiNi and CuZnSn, all exhibiting different types of phase transitions. The sample is glued to a contact electrode (here Ag) and immersed into a thermostat. We measure the electrical resistivity of the contact electrode as function of temperature. Due to the fact that the chemical potentials of the sample and the contact electrode should be equal (µ s = µ e ) the electron gas of the contact electrode "feels" a phase transition taking place in the investigated sample. Therefore we observe kinks in the resistivity plot of the contact electrode which easily localize the proper critical temperatures: T C (Gd), T N (Cr) and T struct (TiNi, CuZnSn). The proposed method visualizes the prevailing role of the chemical potential at phase transitions and provides a completely new ("remote") tool to detect critical points in solids.
IntroductionThe chemical potential related to the electron gas of a system can be considered as a global quantity able to reflect all critical (or characteristic) points connected with different types of phase transitions (transformations) possible to appear in solids with varying temperature, pressure, concentration, etc. . Direct observation of the chemical potential critical behaviour has been performed by the use of electrochemical cells [21,22]. A quite new approach anticipated theoretically [25] is based on the temperature dependence of the resistivity of the contact electrode connected to a sample exhibiting phase transitions. Due to this method the critical temperatures of the sample should be observed as subtle but measurable kinks in the resisivity plot of the reference electrode. Astonishigly enough, the effect really exists. Here we report on some direct observations which allow to localize critical temperatures connected with different types of phase transitions taking place in Gd, Cr, TiNi and CuZnSn materials.