In Fig. 2(a) we show the projected

In Fig. 2(a) we show the projected density of states (PDOS) of the pristine BNNT for the majority (up) and minority (down) spins comparison. Fig. 2(b) shows the PDOS on B (black lines), N (redlines), Fe (blue) and Cl (green lines) atoms for the majority and minority spins of the system FeCl3 plus BNNT in more stable con-figurations. The Fermi level is represented by the vertical dotted line. The energy gap calculated for the pristine (10,0) BNNT was4.32 eV, that agrees with those calculated for BN nanotubes with diameters ≥14˚A in the literature [10,11]. These results indicate the pristine BNNT to behaving as a wide bandgap semiconductor. ForFeCl3plus BNNT system we found an energy gap of 1.17 eV. Fig. 2 also shows a shift in the Fermi energy to the valence band com-pared to the pristine (10,0) BNNT. According to our calculations, this shift of 1.95 eV is going to the valence band. The Fermi level shifts to the valence band it is an evidence that FeCl3acts as an electron acceptor in agreement with calculations performed car-bon nanotube [29]. Another change that occurs when we compare the pristine system with FeCl3plus BNNT is that some levels appear in the region of energy gap. These levels are mainly contribution to the minority spin configuration of Fe atom. For both, majority and minority spins configuration (see Fig. 2(b)), the electronic levels in−8.5 eV to −6.6 eV region band suffer modifications due to
the high hybridization between Cl, B and N orbitals which suggests a covalent interaction between the FeCl3molecule and the BNNT. In the region between −5.5 eV and −4.5 eV in case of the minority spin,a hibridization occurs exclusively between the Fe and Cl molecule atoms.