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Abstract
We report the synthesis of bulk RE1-xAxNiO3 (RE = La, Nd ; A = Sr, Ca) perovskite phases under high oxygen pressure (T = 900 °C, PO2 = 250 bars) and identified a solubility limit of x = 0.07 for phase-pure samples. This solubility limit, shared by the various RE and A combination investigated is likely constrained by the Ni4+ content (t26) whose electronic effect limits doping, regardless the size of RE and A atoms. Alkaline earth (hole) doping induces a decrease in the volume of the unit cell of RE1-xAxNiO3, despite the presence of larger alkaline earth atoms, and an increase in the orthorhombic distortion in the case of RE = Nd (Nd1-xAxNiO3). After topotactic reduction, RE1-xSrxNiO2 infinite-layer were obtained by mixing the perovskite phase with 2 moles of CaH2 in a tube sealed under secondary vacuum and treated at low temperature (250°C). Thermogravimetric analysis was used to determine the oxygen stoichiometry of the compounds with accuracy. We find that while the perovskite parent compound RENiO3 displays a high crystalline quality, regardless the nature of the rare-earth (Nd or La), marked stacking faults are present in reduced NdNiO2 infinite-layer, as determined by X-ray diffraction measurements using synchrotron radiation. High pressure diffraction experiment further demonstrate the role of pressure in attenuating the effect of these stacking faults that were also partially simulated and modelled using the FAULTs program. These defects are virtually absent for Sr2+ doping at 7 % or when Nd is replaced by La. The occurrence of such stacking faults is confirmed by HRTEM analysis in the case of NdNiO2. These stacking faults are more pronoucened in the reduced infinite layer compositions for which the parent perovskite structure is more distorted, as measured by the departure of the Ni-O-Ni angle from 180°, establishing therefore a memory effect between the distortion of the perovskite structure and the occurrence of stacking faults after reduction. The more the perovskite structure is distorted, the greater the stacking fault rate. Finally, we report and discuss the magnetic properties, the electrical resistivity and the specific heat of La and Nd based infinite layer compositions with respect to their structural properties. More specifically, we shed light on the contribution of f-electrons of Nd3+ to the specific heat and discuss the possible signature of spin glass state in LaNiO2 through magnetic and specific heat measurements
