Fig. 2(a)–(c), (f) and (g) shows th

Fig. 2(a)–(c), (f) and (g) shows the typical FE-SEM images of the
prepared pure ZnO nanoparticles at 750 C and Zn1xMgxO nanomaterials
at 750, 850, 900 1000 C for 50 min, respectively.When the
growth temperature is at 750 C, ZnO and Zn1xMgxO exhibit nanoparticles,
their average diameters are about 0.05 and 1.5 lm. With
the increase of growth temperature, the products are evolved into
partially opened nanowire-on-spherical shells at 850 C, hemispheric
shells at 900 C and chain-like nanoparticles at 1000 C,
and their average diameters are bout 5, 7 and 0.05 lm, respectively.
To clearly indicate the partially opened nanowire-on-spherical
shells at 850 C, the magnified SEM images for the outside and internal
structures were shown in Fig. 2(d) and (e). It will be found that
the ZnO nanowires are formed on the outside and internal surfaces,
the nanowires are 15 nm in diameter and 400 nm in the length.
EDX measurements have been carried out on the compositions
of the synthesized Zn1xMgxO nanomaterials, as shown in Fig. 3.
The results indicate that the synthesized Zn1xMgxO nanomaterials
are composed of Zn, Mg and O elements, the signal of Si originates
from the quartz glass substrate, as shown in Fig. 3(b)–(e). Moreover,
no Mg element was detected in pure ZnO nanoparticle at
750 C, as shown in Fig. 3(a). The EDX measurement results indicate
that when the growth temperatures are at 750, 850, 900 and
1000 C, the corresponding molar ratios of Mg in Zn1xMgxO
nanomaterials are determined to be x = 2.87%, 3.51%, 4.43% and
5.01%, respectively. The Mg content is increased with the increase
of growth temperature. It is worth noting that all the samples were
prepared under the same condition, the only difference is the
growth temperature, so, the difference of Mg content in Zn1xMgxO
nanomaterials is induced by the growth temperature, because that
the increasing amount of Mg atom was vaporized with the increase