In this thesis, it was shown the strained nanometre size chromium oxide particles embedded in a single crystallise dielectric matrix exhibit magneto-electric coefficients several orders of magnitude larger than the linear terms in bulk Cr2O3 . These clusters are studied in a double tunnel junction Fe/MgO-Cr-MgO/Fe and their magnetization varies under bias voltage, opening the possibility of efficient use of electric field for controlling the magnetization of the material. It also provides evidence for the occurrence of a significant spontaneous electric polarization on the chromium oxide particles which not only behave as super-paramagnetic but also as super-paraelectric material. The electric polarization is of order of 0,22 μC cm-2 at low temperature. In order to study the electric and magnetic proprieties of these clusters with different transport conditions compared to the double tunnel junction in reference, we reproduced smaller clusters in dielectric matrix MgO as the upper magnetic layer of iron is replaced by a non magnetic layer Pd.In the second part of our work, we used a non- linear optical method to observe the spontaneous polarization at room temperature.The magneto-transport measurements at room temperature do not allow to study the electrical polarization in the Cr2O3, since the tunnel magnetoresistance measured RT is zero. We therefore sought an alternative method of generating the second harmonic which is a nonlinear optical method, which can provide information on the state of the electric polarization in a non- centrosymmetric material. It has been used in our case to determine the super- cluster Cr2O3 paraelectric at room temperature of chromium oxide polarization .Under application of a positive voltage , the variation of the SHG intensity gradually changing to 7 V with 40 % of the reports . We eliminated two major phenomena may induce this change as the influence of capacitive loads or a plasmonic effect , to suggest that this variation is due to the spontaneous polarization is aligned along the applied electric field. The variation of the SHG is observed for an electric field applied in the plane , but it shows instability . We attribute this change in this case an electro- migration in the MgO . we show the SHG variation in function of the voltage for several junctions studied an electric field perpendicular . It can be adjusted by a Langevin function of applied electric field.