Seismic interferometry has been used to detect spatio-temporal changes of seismic scattering properties (e.g. Obermann et al. 2013a). At Sakurajima, one of the most active volcanoes in Japan, a dike intrusion took place on 15 August 2015, and large ground deformation was observed (e.g. Hotta et al. 2016). Such a dike may work as a new scatterer for seismic waves. Therefore, we applied seismic interferometry to detect changes in seismic scattering properties associated with this event. We used the vertical components of ambient seismic noise data at 1 – 2 Hz recorded at 6 JMA stations from 1 January 2012 to 31 August 2015. We calculated coherences between reference CCFs (stacked over 2012 and 2013) and daily CCFs, and found that all station pairs showed significant decreases of coherences before and after the dike intrusion. To locate the region where the seismic scattering properties changed, we used sensitivity kernels calculated from 2D radiative transfer model. Parameters of scattering and intrinsic absorption that are needed to calculate sensitivity kernels were estimated by modeling the space-time distribution of energy density of active shot records. The best-fit parameters were as follows: Mean free path of Rayleigh waves was 1.2 km at 1 – 2 Hz, and intrinsic absorption Q was 62.8f (f is the frequency). Then, we calculated the differences between mean values of coherence in 2014 and those of from 16 August 2015 to 31 August 2015 (hereafter ΔC). Assuming that one seismic scatterer appeared on the surface projection of the dike, we searched the best location of the scatterer to explain observed ΔC. That was located at the same place as the dike determined by using geodetic data (Hotta et al. 2016) with an accuracy of about a few km, and the change of scattering coefficient (Δg) was estimated as 1.4 km-1. Acknowledgements: We used seismograms recorded by JMA. Active seismic experiments were conducted by DPRI, Kyoto University, other 8 universities, and JMA.