Scaling studies of temperature dependence of electric conductivity and electric modulus spectra of solid solution Sr2-xLaxSnO4 (x ≤ 0.10) Ruddlesden Popper Oxide.

• The conventional ceramic route successfully synthesized all the samples. • Jonscher power law was applied to the ac conductivity of all samples to study the conduction mechanism. • The conductivity spectrum of all samples follows Ghosh and Rolling scaling. • Kohlrausch-William-Watt function was applied to M ″ (f) to study the relaxation mechanism of samples. • Both the scaling behaviors reflected the temperature-independent conduction mechanism in the system. The mixed ionic and electronic conductor oxide with formula Sr 2-x La x SnO 4 (S2LS) within x ≤ 0.10 were synthesized via the conventional ceramic route and investigated. The structural analysis revealed the formation of single-phase materials with a tetragonal crystal structure. The presence of Sn in the form of Sn4+/Sn2+ ions and oxygen vacancies in the synthesized samples were investigated by X-ray photoelectron spectroscopy. The alternating current (AC) conductivity and modulus spectra of S2LS systems were obtained as functions of frequency and temperature and further scaled. The AC conductivity data were analyzed using Jonscher's power law (JPL) fitting to determine the hopping frequencies, DC conductivities, and power exponents. The obtained activation energy value suggests the dependence of conductivity primarily on the mobility of charge carriers. The conductivity spectra were analyzed using various formalisms, viz., Ghosh scaling and Rolling scaling, to understand the conduction mechanism. The scaling behaviors of AC conductivity and modulus spectra reflect the temperature-independent conduction mechanism of the system. [Display omitted] The following graph shows Rietveld refinement XRD pattern, high-resolution scanning electron micrograph, scaled conductivity and scaled modulus as a function of frequency at different temperatures. [ABSTRACT FROM AUTHOR]