Tie zero-magnetic-field oscillation behavior of spin torque nano-oscillator(STNO) with a perpendicularly magnetized free layer with second-order uniaxial anisotropy is studied theoretically based on the Landau-LifshitzGilbert-Slonczewski equation.It is demonstrated numerically that the second-order uniaxial anisotropy plays a significant role in the occurrence of a zero-magnetic-field steady-state precession,which can be understood in terms of the energy balance between the energy accumulation due to the spin torque and the energy dissipation due to the Gilbert damping.In particular,a relatively large zero-magnetic-field-oscillation current region,in which the corresponding microwave frequency is increased while the threshold current still maintains an almost constant value,can be obtained by modulating the second-order uniaxial anisotropy of the free layer.These results suggest a tunable zero-magnetic-Reld STNO,and it may be a promising configuration for STNO’s applications in future wireless communications. Tie zero-magnetic-field oscillation behavior of spin torque nano-oscillator (STNO) with a perpendicularly magnetized free layer with second-order uniaxial anisotropy is derived theoretically based on the Landau-Lifshitz Gilbert-Slonczewski equation. It is demonstrated numerically that the second- order uniaxial anisotropy plays a significant role in the occurrence of a zero-magnetic-field steady-state precession, which can be understood in terms of the energy balance between the energy accumulation due to the spin torque and the energy dissipation due to the Gilbert damping . In particular, a relatively large zero-magnetic-field-oscillation current region, in which the corresponding microwave frequency is increased while the threshold current still still maintains an almost constant value, can be obtained by modulating the second-order uniaxial anisotropy of the free layer. These results suggest a tunable zero-magnetic-Reld STNO, and it may be a promising configuration for STNO’s applications in future wireless communications.