The extremely large non-saturated magnetoresistance is an unusual property of many semimetals, some of which have topological quantum states. In the present paper, the non-stoichiometry effect on the magnetoresistance is systematically investigated for the Weyl semimetal WTe2. The as-grown samples have a slight difference in Te vacancies, whose magnetoresistance and Hall resistivity are measured and analyzed with a two-carrier model. The fitting results show that the extreme magnetoresistance is strongly dependent on the residual resistivity ratio, which is interpreted as the degree of non-stoichiometry and the ratio of electron-type and hole-type carriers. Such an electron-hole compensation mechanism is further confirmed by the measurements on the annealed samples with artificial Te vacancies. The non-stoichiometry effect is eventually understood in terms of electron doping which breaks the balance between electron-type and hole-type carriers. These facts demonstrate that the compensation effect is the dominant mechanism of the extreme magnetoresistance in WTe2, in spite of other possible origins.
Published in: "arXiv Material Science".