A high-sensitivity plasmonic refractive-index sensor based on the asymmetrical coupling of two metal-insulatormetal waveguides with a nanodisk resonator is proposed and simulated in the finite-difference time domain.Both analytic and simulated results show that the resonance wavelengths of the sensor have an approximate linear relationship with the refractive index of the materials which are filled into the slit waveguides and the diskshaped resonator.The working mechanism of this sensor is exactly due to the linear relationship,based on which the refractive index of the materials unknown can be obtained from the detection of the resonance wavelength.The measurement sensitivity can reach as high as 6.45 × 10~(-7),which is nearly five times higher than the results reported in the recent literature[Opt.Commun.300(2013) 265].With an optimum design,the sensing value can be further improved,and it can be widely applied into the biological sensing.The sensor working for temperature sensing is also analyzed. A high-sensitivity plasmonic refractive-index sensor based on the asymmetrical coupling of two metal-insulatormetal waveguides with a nanodisk resonator is proposed and simulated in the finite-difference time domain. Both analytic and simulated results show that the resonance wavelengths of the sensor have an approximate linear relationship with the refractive index of the materials which are filled into the slit waveguides and the diskshaped resonator the working mechanism of this sensor is exactly due to the linear relationship, which on the refractive index of the materials unknown can be obtained from the detection of the resonance wavelength. The measurement sensitivity can reach as high as 6.45 × 10 -7, which is nearly five times higher than the results reported in the recent literature [Opt. Commun. 300 (2013) 265] .With an optimum design, the sensing value can be further improved, and it can be widely applied into the biological sensing. The sensor working for temperature sensing is also analyzed.