Korean Journal of Remote Sensing (대한원격탐사학회지)

Korean Society of Remote Sensing (대한원격탐사학회)
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Radar Measurement of Slow Deformation in the Baekdusan Stratovolcano

  • Kim, Sang-Wan (Rosenstiel School of Marine and Atmospheric Science, University of Miami) ;
  • Won , Joong-Sun (Department of Earth System Sciences, Yonsei University)
  • Published : 2005.06.01
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Abstract

Baekdusan is a Cenozoic stratovolcano in which a series of micro-seismic events and gaseous emissions have been reported in 1990s. Two-pass DInSAR technique was applied to determine displacement in the volcano by using 10 ERS SAR and 41 JERS-1 SAR datasets. Most interferometric phases out of 58 JERS-1 differential interferograms showed concentric fringe patterns that correlated with elevation. From an analysis of fringe-duration relation, the fringe patterns were found to be severely distorted specifically by stratified troposphere. To estimate the tropospheric delay, we used the data in the Sobaeksan located about 20 km away from the summit of Baekdusan. The maximum and mean magnitudes of the phase delay in the Baekdusan were respectively 13.8 cm and 3.8 cm over 1200 m in altitude. After removing tropospheric effects, a mean inflation rate was estimated to be about 3 mm per year from 1992 to 1998. Although the inflation rate of the volcano is inconclusive without ground truth data, the results indicate that there exists slow upward deformation in the Baekdusan volcano.

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References

  1. Amelung F., S. Jonsson, H. Zebker, and P. Segall, 2000. Widespread uplift and 'trapdoor' faulting on Galapagos volcanoes observed with radar interferometry, Nature, 407: 993-996 https://doi.org/10.1038/35039604
  2. Beauducel F., P. Briole, and J.-L. Froger, 2000. Volcano-wide fringes in ERS synthetic aperture radar interferograms of Etna (1992-1998): Deformation or tropospheric effect?, Journal of Geophysical Research, 105(16): 391-402
  3. Hetland, E. A., F. T. Wu, and J. L. Song, 2004. Crustal structure in the Changbaishan volcanic area, China, determined by modeling receiver functions, Tectonophysics, 386: 157-175 https://doi.org/10.1016/j.tecto.2004.06.001
  4. Horn S. and H.-U. Schmincke, 2000. Volatile emission during the eruption of Baitoushan volcano (China/North Korea) ca. 969 AD, Bulletin of Volcanology, 61: 537-555 https://doi.org/10.1007/s004450050004
  5. Massonnet D., P. Briole, and A. Arnaud, 1995. Deflation of Mount Etna monitored by spaceborne radar interferometry, Nature, 375: 567-570 https://doi.org/10.1038/375567a0
  6. Massonnet D. and K. L. Feigl, 1998. Radar Interferometry and its Application to Changes in the Earth's Surface, Reviews of Geophysics, 36: 441-500 https://doi.org/10.1029/97RG03139
  7. Seymour, M. S., 1999. Refining Low-Quality digital elevation models using synthetic aperture radar interferometry, The University of British Columbia, Ph.D. Dissertation
  8. Muller J.-P. and Backes D., 2003. Quality assessment of X- and C-SRTM with ERS-tandem DEMs over 4 European CEOS WGCV test sites, Proceedings of FRINGE 2003 Workshop, 1-5 Dec. 2003, Frascati, Italy
  9. Tarayre H. and Massonnet D., 1996. Atmospheric propagation heterogeneities revealed by ERS-1 interferometry, Geophysical Resesarch Letters, 23: 989-992 https://doi.org/10.1029/96GL00622