Scientific Quarterly Journal of Geosciences

Scientific Quarterly Journal of Geosciences

The effect of joint density on P-wave velocity

Document Type : Original Research Paper

Authors
Yaghoob Zarei 1
Ali Uromeihy 2
MohammadReza Nikoodel 3
1 Ph.D., Department of Engineering Geology, Faculty of Basic Sciences, Tarbiat Modares University, Tehran, Iran
2 Professor, Department of Engineering Geology, Faculty of Basic Sciences, Tarbiat Modares University, Tehran, Iran
3 Associated Professor, Department of Engineering Geology, Faculty of Basic Sciences, Tarbiat Modares University, Tehran, Iran
10.22071/gsj.2019.151144.1546
Abstract
In this labratory study, the effect of joint density (number and spacing) on the pressure wave velocity was researched in pyroclastic rocks. After determining the physical properties, the P-wave velocities of intact rock samples were measrued. Then, an artificial joint perpendicular to the measuring direction was created in each sample, and the wave velocity tests were repeated. These tests were continued up to 5 joints with two sets of 2 and 5 cm spacing. Consequently, the data were analyzed using the statistical methods. The results show that the P-wave velocity was decreased by increasing the number of joints in both spacing sets, and thus an inverse linear relationship was obtained. However, as the number of joints increases, the reduction rates of wave velocity were different at two spacing sets. More precisely, up to 3 joints, the reduction rate in the 5 cm spacing set was more than that in the other set. Nonetheles, after the third joint, the decreasing rate in the 2 cm spacing set became greater. Generally, the shorter spacing had a more reduction (attenuation) in the P-wave velocity. In this regard, at a total of 5 joints, the reduction rate of the P-wave velocity in 2 cm spacing set was more than that in the other set.
Keywords
Rock mass
number of joints
spacing
ultrasonic waves
P-wave velocity

Subjects

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Scientific Quarterly Journal of Geosciences
Volume 29, Issue 115 - Serial Number 115
Volume 29, Serial Number 115, Spring 2020
Spring 2020
Pages 151-162