The researchers have successfully synthesized a series of CaV1-xWxO3 (x=0.1-0.33) perovskite oxides and studied their structural, electrical, and magnetic properties.
The crystal structure analysis shows that the compounds form an orthorhombically distorted perovskite of the GdFeO3 type, with the unit cell parameters increasing as the tungsten content x increases. This is attributed to the replacement of smaller V4+ cations by larger V3+ and W6+ cations in the B-site.
The electrical transport measurements reveal a systematic evolution from metallic behavior for low tungsten content (x=0.1) to insulating behavior for the end composition CaV0.67W0.33O3. The insulating CaV0.67W0.33O3 exhibits two activation regimes in the resistivity - a simple activation at high temperatures and variable range hopping at low temperatures, characteristic of a Mott insulator.
Magnetic susceptibility measurements show that the low tungsten content samples (x=0.1-0.25) are Pauli paramagnets, while CaV0.67W0.33O3 displays a spin-glass-like behavior with a freezing temperature of 27.5 K. The effective magnetic moment of V3+ in CaV0.67W0.33O3 is reduced compared to the spin-only value, likely due to the distortion of the octahedral ligand field.
The specific heat of CaV0.67W0.33O3 exhibits a broad anomaly at 34 K, attributed to the magnetic disorder in the system. The magnetic entropy reaches a value close to the theoretical limit for V3+ (d2) ions, confirming the localized nature of the magnetic moments.
Overall, the results demonstrate that the CaV1-xWxO3 system provides a platform to study the metal-insulator transition driven by the interplay of structural distortions, electron correlations, and magnetic ordering in perovskite oxides.
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