GEP  Vol.3 No.8 , October 2015
Application of Google Earth in Modern River Sedimentology Research
Abstract: Google Earth, a software based on satellite’s images and database of navigation, gains features of high resolution, integrated images, quick update, convenience, simpleness and free cost. Practice of this software shows that it plays an important role in mapping, construction and river research. Based on the fundamental features of Google Earth, this passage makes an introduction to its application in studying modern river sedimentology through the case study of the Yellow River. The results show that Google Earth satellite’s high-resolution images and image overlay functions make it easy for users to quickly navigate river, determine the type of river, track the river flows and measure the terrain slope; the software’s “Ruler” and “Add Path” functions make it easy for users to measure channel width, curvature, amplitude, wavelength, size, morphology of point-bar and other river parameters; the software’s “Historical Image” function has important significance in the study of modern river migration, sedimentary evolution and river geomorphological shape during different seasons.
Cite this paper: Zhou, X. and Wang, H. (2015) Application of Google Earth in Modern River Sedimentology Research. Journal of Geoscience and Environment Protection, 3, 1-8. doi: 10.4236/gep.2015.38001.

[1]   Shi, X.L. (2014) The Application of Google Earth to Coalfield of Panjiayao Block with 3D Seismic Exploration Technology. Journal of Engineering Geophysics, 4, 457-461.

[2]   Wang, H.G., Ma, C.L., Ye, Y.L., Jia, W.J. and Zhou, J.P. (2007) Application of Google Earth to Oil Exploration. Journal of Geophysical Prospecting Equipment, 4, 306-308.

[3]   Ye, F.M. and Han, Z.M. (2009) Application of Google Earth in the Railway Survey Design. Railway Survey, 6, 43-46.

[4]   Lin, Y., Li, X.J. and Pei, Z.Q. (2007) Use Google Earth Satellite Images to Assist the Design in the Construction of Geophysical Exploration. Journal of Geophysical Prospecting Equipment, 17, 48-52.

[5]   Li, P.C. (2012) Application of Google Earth to Railway Surveying and Mapping Work. Railway Survey, 1, 15-18.

[6]   Ren, H.Q., Chen, H. and Zhang, H.Q. (2011) Application of Google Earth Software to the Surveying and Mapping of Ribbon Topographic Map. Journal of Surveying and Mapping Technology and Equipment, 3, 36-37.

[7]   Dou, C.H. (2011) Application of Google Earth in Water Conservancy and Hydropower Survey and Mapping. Journal of Geospatial Information, 5, 53-55.

[8]   Duan, H.J. and Bian, S.F. (2008) Research on the Visualization of Ocean Physical Field Data Based on the Google Earth. Journal of Marine Surveying and Mapping, 28, 36-39.

[9]   Chien, N.Q. and Keat Tan, S. (2011) Google Earth as a Tool in 2-D Hydrodynamic Modeling. Computers & Geosciences, 37, 38-46.

[10]   Goudie, A. (2013) Characterising the Distribution and Morphology of Creeks and Pans on Salt Marshes in England and Wales Using Google Earth. Estuarine, Coastal and Shelf Science, 129, 112-123.

[11]   Shi, S.Y., Hu, S.Y., Fen, W.J. and Liu, W. (2012) Building Geological Knowledge Database Based on Google Earth Software. Journal of Sedimentary, 30, 869-878.

[12]   Li, Y.P., Wu, S.H. and Yue, D.L. (2008) The Quantitative Relationship between Channel Width and Point-Bar Length of Modern Meandering River. Journal of Daqing Petroleum Geology and Development, 27, 19-22.

[13]   Zhang, B. (2007) The Form and Origin of Jialing River Meander in China. Chinese Science Bulletin, 52, 2671-1682.

[14]   Zhang, C.M., Yin, T.J. and Zhu, Y.J. (2010) The Depositional Model of Shallow Water Delta. Journal of Sedimentary, 28, 933-944.

[15]   Guo, X.B. (2012) Application of Google Earth to the Measurement in the Geology Exploration. Journal of Mining Census, 3, 523-526.

[16]   Meng, F.X. (2008) Application of Google Earth in Geological Exploration. Journal of Coal Technology, 7, 130-131.

[17]   Wang, D. and Zhao, Z.X. (2006) Explanation of Using Google Earth. Journal of Engineering Geology and Computer Applications, 9, 23-31.