Sentence examples for magnetic behavior at from inspiring English sources

The films also exhibited magnetic behavior at low temperatures.

Recently, it has been found that the magnetic behavior at the interface between the cores of Ni (FM) nanoparticles with NiO (AFM) shells of various sizes can be altered [6].

As the electron spins of these sublattices are not exactly antiparallel (with a canting angle of <0.1°), a weak ferromagnetic interaction is resulted, and this effect dominates the magnetic behavior at room temperature [4].

In the interior of CNT channels the α-Fe and Fe3C nanoparticles were observed to be coupled by a strong exchange interaction and to exhibit magnetic behavior at room temperature.

The magnetization measured in zero field-cooled (MZFC) and field-cooled (MFC) modes from 20 to 380 K in a field of 200 Oe for the samples UD700 (a) and UD1000 (b). Figure 5 The schematic plot for understanding the magnetic behavior at 300 K for undiluted samples.

So, as first approximation, a magnetic particle at temperature T will have the same magnetic behavior as a particle at temperature (T_0,) but with an effective magnetic gradient given by Eq. 19.

Both of the Mn12 clusters modified by the conjugated polymer (Mn12-P1 and Mn12-P2) show paramagnetism in the range of 2 300 K, and no SMM magnetic behavior is observed at low temperature.

(ii) The shift of the FC hysteresis loops is probably related to the magnetic behavior of the frustrated AFM domains at the shell which can be regarded as a two-dimensional diluted AFM in a field (DAFF) recently reported by Benitez et al. [32] This DAFF shell can be examined by measuring magnetic field-dependent thermoremanent magnetization.

MFM images of Mn-doped ZnO NR arrays and single nanorod were studied in nanoscale at room temperature and demonstrate magnetic behavior.

The temperature at which they change their magnetic behavior from ferro- or ferrimagnetic to paramagnetic is called Curie temperature (T C ).

The magnetic behavior of the materials was evaluated by magnetization (M) variation with applied magnetic field (H) at different temperatures.