Hole-doping dependence of percolative phase separation in Pr(0.5-delta)Ca(0.2+delta)Sr(0.3)MnO(3) around half doping
Abstract
We address the problem of the percolative phase separation in polycrystalline samples of Pr0.5-δCa0.2+δSr0.3MnO3 for -0.04≤ δ ≤ 0.04 (hole doping n between 0.46 and 0.54). We perform measurements of X-ray diffraction, dc magnetization, ESR, and electrical resistivity. These samples show at TC a paramagnetic (PM) to ferromagnetic (FM) transition, however, we found that for n>0.50 there is a coexistence of both of these phases below TC. On lowering T below the charge-ordering (CO) temperature TCO all the samples exhibit a coexistence between the FM metallic and CO (antiferromagnetic) phases. In the whole T range the FM phase fraction (X) decreases with increasing n. Furthermore, we show that only for n≤ 0.50 the metallic fraction is above the critical percolation threshold XC 15.5%. As a consequence, these samples show very different magnetoresistance properties. In addition, for n≤ 0.50 we observe a percolative metal-insulator transition at TMI, and for TMI<T<TCO the insulating-like behavior generated by the enlargement of X with increasing T is well described by the percolation law -1=σ (X-XC)t, where t is a critical exponent. On the basis of the values obtained for this exponent we discuss different possible percolation mechanisms, and suggest that a more deep understanding of geometric and dimensionality effects is needed in phase separated manganites. We present a complete T vs n phase diagram showing the magnetic and electric properties of the studied compound around half doping.
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