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Compressive–tensile rock markings

Published online by Cambridge University Press:  02 October 2019

Robert G. Bednarik Open the ORCID record for Robert G. Bednarik [Opens in a new window]
Robert G. Bednarik*
Affiliation:
ICRAD, Hebei Normal University, Shijiazhuang, China IFRAO, PO Box 216, Caulfield South, Melbourne, VIC 3162, Australia
*
Author for correspondence: Robert G. Bednarik, Email: auraweb@hotmail.com
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Abstract

A form of natural rock marking is described from a site on the coast of Fujian in China. Having been defined as rock art, it has now been found to be natural, caused by the release of massive kinetic energy in collisions between large blocks of granite. A combination of compressive and tensile stresses has yielded geometric changes to the fabric of the rock, and the selective weathering of modified parts of the rock has produced visually distinct, large surface markings resembling a rising Sun. The processes involved are considered in the light of research into the similar effects of explosives on rock.

Keywords

Kinetic energyrock markingimpactexplosivegraniteFujian ProvinceChina
Type
Rapid Communication
Information
Geological Magazine , Volume 156 , Issue 12 , December 2019 , pp. 2113 - 2116
Copyright
© Cambridge University Press 2019 

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References

Banadaki, MD and Mohanty, B (2012) Numerical simulation of stress wave induced fractures in rock. International Journal of Impact Engineering 40–41, 1625.CrossRefGoogle Scholar
Bednarik, RG (1992) A new method to date petroglyphs. Archaeometry 34, 279–91.CrossRefGoogle Scholar
Bednarik, RG (1994) The discrimination of rock markings. Rock Art Research 11, 2344.Google Scholar
Bednarik, RG (2007) Rock Art Science: The Scientific Study of Palaeoart, 2nd edn. New Delhi: Aryan Books International (1st edn 2001, Brepols, Turnhout).Google Scholar
Bednarik, RG (2019) Tribology in Geology and Archaeology. New York: Nova Science Publishers.Google Scholar
Donzé, FV, Bouchez, J and Magnier, SA (1997) Modeling fractures in rock blasting. International Journal of Rock Mechanics and Mining Sciences 34, 1153–63.CrossRefGoogle Scholar
Dragovich, D (1969) The origin of cavernous surfaces (tafoni) in granitic rocks of southern South Australia. Zeitschrift für Geomorphologie 13, 163–81.Google Scholar
Esen, S, Onederra, I and Bilgin, HA (2003) Modelling the size of the crushed zone around a blasthole. International Journal of Rock Mechanics and Mining Sciences 40, 485–95.CrossRefGoogle Scholar
Guerra, A, Petr, V and Griffiths, DV (2013) Radial fractures in rock under the action of explosives. Paper presented to 6th International Conference on Discrete Element Methods, 5–6 August, Golden, CO. Available at: https://www.semanticscholar.org/paper/FORMATION-OF-RADIAL-FRACTURING-IN-ROCK-UNDER-THE-OF-Guerra-Petr/1297fccb0fbbd383a8f136c89e03a7891942a1ef.Google Scholar
Kutter, HK and Fairhurst, C (1971) On the fracture process in blasting. International Journal of Rock Mechanics and Mining Sciences 8, 181202.CrossRefGoogle Scholar
Martini, IP (1978) Tafoni weathering, with examples from Tuscany, Italy. Zeitschrift für Geomorphologie 22, 4467.Google Scholar
McHugh, S (1983) Crack extension caused by internal gas pressure compared with extension caused by tensile stress. International Journal of Fractures 21, 163–76.CrossRefGoogle Scholar
Torbica, S and Lapčević, V (2014) Rock breakage by explosives. European International Journal of Science and Technology 3, 96104.Google Scholar
Torbica, S and Lapčević, V (2018) Rock fracturing mechanisms by blasting. Underground Mining Engineering 32, 1531.Google Scholar
Whittaker, BN, Singh, RN and Sun, G (1992) Rock Fracture Mechanics: Principles, Design, and Applications. Amsterdam & New York: Elsevier, Developments in Geotechnical Engineering no. 71.Google Scholar