NH21A-1813
Radon and gamma rays anomalies observed in northern Taiwan: a possible connection with the seismicity near the subduction zone

Tuesday, 15 December 2015
Poster Hall (Moscone South)
Ching-Chou Fu1, Lou-Chuang Lee1, Tsanyao F Yang2, Peng-Gang Wang1, Tsung-Kwei Liu3, Vivek Walia4, Cheng-Hong Chen3, Cheng-Horng Lin5, Tzu-Hua Lai6, Gioacchino Giuliani7 and Dimitar Ouzounov8, (1)Institute of Earth Sciences Academia Sinica, Taipei, Taiwan, (2)NTU National Taiwan University, Taipei, Taiwan, (3)Natl Taiwan Univ, Dept. Geosciences, Taipei, Taiwan, (4)NCREE National Center for Research on Earthquake Engineering of Taiwan, Taipei, Taiwan, (5)Academia Sinica, Taipei, Taiwan, (6)Central Geological Survey, Taipei, Taiwan, (7)Permanent Foundation G. Giuliani, L'Aquila, Italy, (8)American Geophysical Union, Washington, DC, United States
Abstract:
Taiwan is tectonically situated in a terrain resulting from the oblique collision between the Philippine Sea plate (PHS) and the Eurasian plate (EU). The continuous observations of soil radon for earthquake studies at the Tapingti station (TPT) have been recorded and are compared with the data from gamma rays observations at the Taiwan Volcano Observation station(YMSG), located north to the TPT station. Some anomalous high radon concentrations and gamma-ray counts at certain times can be identified. It is noted that the significant increase of soil radon concentrations were observed and followed by the increase in gamma-ray counts several days before the earthquakes, which occurred in eastern Taiwan. Many of these earthquakes are located within the subducting PHS beneath the EU to the north along the Ryukyu trench in northern Taiwan (e.g., ML=6.3 April 20, 2015). It is suggested that the pre-earthquake activities may be associated with slow geodynamic processes at the subduction interface, leading to the PHS movement to trigger radon enhancements at TPT station. Furthermore, the further movement of PHS may be locked by EU and accumulate elastic stress resulting in the increase of gamma rays due to an increase in the porosity and fractures below the YMSG station. The continuous monitoring on the multiple parameters can improve our understanding of the relationship between the observed radon and gamma-ray variations and the regional crustal stress/strain in the area.