The coastal zone comprises a narrow strip of coastal lowlands and a vast area of coastal waters.
It has become an important site for extensive and diverse economic activities. The rise in sea level,
which is attributed to global warming, has resulted in coastal sand drainage around the world, thus
mean sea level will result in the retreat of unprotected coastline [1,2]. One of the common methods
of preventing coastal erosion is covering the surface of the sandy beach with concrete. However, this
method has a significant impact on the environment and destroys the surrounding landscape.

Beachrock is a sedimentary rock that occurs in the intertidal zone of sandy beaches, mainly in the
tropics and subtropics [3]. It is composed of the same material as the surrounding beach, and most of
the cement material is carbonated. Most of the research on beachrock is related to its geological or
chemical properties, and there is very little literature on the underground structure of beachrock.
There have been a few cases of electrical exploration on Thassos Island, Greece [4]. To elucidate the
formation process of beachrock, it is important to understand the structure of its underground and
surrounding area. Kubo et al. [5] investigated beachrock on Yagaji Island, Okinawa, Japan, using a
direct current (DC) electrical survey on a seismic surface and showed the results of the structure
around the seashore to a depth of more than 10 m. Insufficient data in the South East Asian country
related to recent beachrock sedimentary is a challenge for further study because of the weathering
process is extremely rapid, especially is intertropical areas. This study serves as a pilot research study
on the beachrock sedimentary processes at intertropical areas and compares the rock properties of
the artificial beachrock, which is fabricated using the microbially induced carbonate precipitation
(MICP) method, as a solution to coastal erosion as new revetment technology with a self-repair
function. Upon receiving successful results following MICP treatment using marine ureolytic
bacterium for the desired engineering application, further studies were carried out to (i) examine the
underground structure of natural beachrock based on a geophysical survey, (ii) develop a 3D
beachrock structure, and (iii) identify the physical and mechanical properties, such as porosity,
compressional wave (P-wave) velocity (VP), shear wave (S-wave) velocity (VS), and strength
characteristics of artificial beachrock. These properties were relatively comparable with those of
natural beachrocks and were significantly determined by the precipitated crystals based on the MICP
treatment.