The number of works dealing with th

The number of works dealing with the synthesis of spinel-type MnIn2O4 is limited which is probably due to the difficulties in the stabilization of this phase. Indeed, the synthesis of spinel-type
Requires special conditions of temperature and pressure to enable either indium or manganese cations to occupy the tetrahedral sites.For spinel oxides,the tetrahedral sites are usually occupied by cations with radius less than the half of the radius of oxygen ions(r(O2-)=140 pm).therefore,a large deformation of the oxygen sublattice is required for placing the large indium or manganese cations (r(In3+)=76 pm,r(Mn2+)=80 pm ;both cations are 4-fold coordinated) at the tetrahedral sites. This deformation in oxygen framework can take place at high temperatures and pressures.The second problem in synthesizing spinel-type MnIn2O4 is the stabilization of the Mn2+ cations and the prevention of the oxidation of Mn2+ -materials to Mn2+O3 and MnO2.Therefore,MnIn2O4 was previously synthesized either by ceramic methods from In2O3 and MnO(mole ratio=1:1) in an inet atmosphere in sealed quartz tubes at 1000 C for 7 days followed by air quenching or by calcination of co-precipitated manganese and indium hydroxides at 1300-1400 C in CO2/CO mixture for 6 hours.More recently.MnIn2O4 was obtained from a precipitate synthesized by citrate method from In2O3 and MnCO3 by heating it at three subsequent temperatures 500,1200 and 1400 C for 12h/cycle in the flowing N2.The high synthesis temperatures do not allow for controlling the degree of inversion in spinel structures and lead to considerable growth of spinel particles.






Accordingly, the goal of this work is to develop a synthesis methodology for obtaining MnIn204 at much lower temperatures if compared to those in the conventional solid state synthesis and to address the structure chemistry and stability of these materials. Such mild conditions prevent
significant growth of spinel crystrals and allow therefore for the stabilization of spinel oxides with smaller crystallite size as well as for obtaining materials with the different degree of inversion.