86 research outputs found
The survey and mapping of sand-boil landforms related to the Emilia 2012 earthquakes: preliminary results.
Sand boils, which are also known as sand blows or sand volcanoes, are among the most common superficial effects induced by high-magnitude earthquakes. These generally occur in or close to alluvial plains when a strong earthquake (M >5) strikes on a lens of saturated and unconsolidated sand deposits that are constrained between silt-clay layers, where the sediments are converted into a fluid suspension. The liquefaction phenomena requires the presence of saturated and uncompacted sand, and a groundwater table near the ground surface. This geological–geomorphological setting is common and widespread for the Po Plain (Italy). The Po Plain (ca. 46,000 km2) represents 15% of the Italian territory. It hosts a population of about 20 million people (mean density of 450 people/km2) and many infrastructures. Thus, the Po Plain is an area of high vulnerability when considering the liquefaction potential in the case of a strong earthquake. Despite the potential, such phenomena are rarely observed in northern Italy, because strong earthquakes are not frequent in this region; e.g., historical data report soil liquefaction near Ferrara in 1570 (M 5.3) and in Argenta 1624 (M 5.5). In the Emilia quakes of May 20 and 29, 2012, the most widespread coseismic effects were soil liquefaction and ground cracks, which occurred over wide areas in the Provinces of Modena, Ferrara, Bologna, Reggio Emilia and Mantov
The survey and mapping of sand-boil landformsrelated to the Emilia 2012 earthquakes: preliminary results
In this report, we present preliminary results using methods to map the detailed micro-morphology of some representative liquefaction features that normally disappear for the aforementioned reasons, or that are recorded only in qualitative terms.
Field surveys and activities were conducted a few days
after the May 20 and 29, 2012, mainshocks (M 5.9, M 5.8, respectively).
The surveys were carried out using global position
system (GPS) and reflex digital cameras. GPS acquisition
(tracklog) was used to record the topographic positions of the
features and to automatically geolocate/geotag the numerous
digital photos acquired. The field data, geomorphological features,
and sand-boil location were loaded into a geodatabase
and mapped using geographic information systems (GIS).
Photogrammetric surveys were carried out on several
sand boils using digital reflex cameras with calibrated 20-mm
fixed lenses. To build high resolution digital elevation models
(DEMs), images were taken from multiple angles to cover the
entire areas of the features of interest
The survey and mapping of sand-boil landforms related to the Emilia 2012 earthquakes: preliminary results.
Sand boils, which are also known as sand blows or sand volcanoes, are among the most common superficial effects induced by high-magnitude earthquakes. These generally occur in or close to alluvial plains when a strong earthquake (M >5) strikes on a lens of saturated and unconsolidated sand deposits that are constrained between silt-clay layers, where the sediments are converted into a fluid suspension. The liquefaction phenomena requires the presence of saturated and uncompacted sand, and a groundwater table near the ground surface. This geological\u2013geomorphological setting is common and widespread for the Po Plain (Italy). The Po Plain (ca. 46,000 km2) represents 15% of the Italian territory. It hosts a population of about 20 million people (mean density of 450 people/km2) and many infrastructures. Thus, the Po Plain is an area of high vulnerability when considering the liquefaction potential in the case of a strong earthquake. Despite the potential, such phenomena are rarely observed in northern Italy, because strong earthquakes are not frequent in this region; e.g., historical data report soil liquefaction near Ferrara in 1570 (M 5.3) and in Argenta 1624 (M 5.5). In the Emilia quakes of May 20 and 29, 2012, the most widespread coseismic effects were soil liquefaction and ground cracks, which occurred over wide areas in the Provinces of Modena, Ferrara, Bologna, Reggio Emilia and Mantov
The survey and mapping of sand-boil landforms related to the Emilia 2012 earthquakes: preliminary results
Sand boils, which are also known as sand blows or sand
volcanoes, are among the most common superficial effects
induced by high-magnitude earthquakes. These generally
occur in or close to alluvial plains when a strong earthquake
(M >5) strikes on a lens of saturated and unconsolidated
sand deposits that are constrained between silt-clay layers
[Ambraseys 1988, Carter and Seed 1988, Galli 2000, Tuttle
2001, Obermeier et al. 2005], where the sediments are converted
into a fluid suspension. The liquefaction phenomena
requires the presence of saturated and uncompacted sand,
and a groundwater table near the ground surface. This geological–
geomorphological setting is common and widespread
for the Po Plain (Italy) [Castiglioni et al. 1997]. The
Po Plain (ca. 46,000 km2) represents 15% of the Italian territory.
It hosts a population of about 20 million people
(mean density of 450 people/km2) and many infrastructures.
Thus, the Po Plain is an area of high vulnerability
when considering the liquefaction potential in the case of a
strong earthquake. Despite the potential, such phenomena
are rarely observed in northern Italy [Cavallin et al. 1977,
Galli 2000], because strong earthquakes are not frequent in
this region; e.g., historical data report soil liquefaction near
Ferrara in 1570 (M 5.3) and in Argenta 1624 (M 5.5) [Prestininzi
and Romeo 2000, Galli 2000]. In the Emilia quakes
of May 20 and 29, 2012, the most widespread coseismic effects
were soil liquefaction and ground cracks, which occurred
over wide areas in the Provinces of Modena, Ferrara,
Bologna, Reggio Emilia and Mantova (Figure 1). These were
the causes of considerable damage to buildings and the infrastructure.
The soil liquefaction and ground cracks were
accompanied by sand boils, which are described in this report.
The spatial distribution and geomorphological setting
of sand boils and ground cracks are also described here. A
detailed three-dimensional (3D) reconstruction of these features
is also presented, which was carried out using terrestrial
photogrammetry.
Since archeological times, fluvial ridges, and in general
sandy deposits on low plains have been the preferred sites for
human infrastructure, colonial houses, roads, etc. Therefore,
it is very important to understand how the local topography/
morphology interacts in the liquefaction processes. Numerous
distinctive seismic landforms were generated by the
May 2012 strong earthquakes (seven with M >5), and in particular,
sand boils and ground fractures. The sand-boil landforms,
also known as sand craters or sand volcanoes, are
formed by low mounds of sand that have been extruded
from fractures [Tuttle 2001]. The cone is a generally shortlived
structure that naturally collapses, starting from the center
holes that mark the water retreat back into the fracture.
Sand boils also occurred along larger cracks (with decimetric
lateral and vertical displacements). Here, the upper scarps
block the formation of craters and allow the deposition of a
sandy layer several centimeters thick (e.g. ca. 4 cm in the San
Carlo crack), on the lower side of the steep slope. These landforms
are highly vulnerable to erosion. After a few weeks,
they are washed out by rain, destroyed by human activity, or
masked by growing crops. Thus, ground surveys that investigate
these events have to be carried out as soon as possible
[Panizza et al. 1981]. In this report, we present preliminary
results using methods to map the detailed micro-morphology
of some representative liquefaction features (Figure 2)
that normally disappear for the aforementioned reasons, or
that are recorded only in qualitative terms
Morphometric analysis of a fresh simple crater on the Moon
In this research we are proposing an innovative method to determine and quantify the morphology of a simple fresh impact crater. Linné is a well preserved impact crater of 2.2 km in diameter, located at 27.7oN 11.8oE, near the western edge of Mare Serenitatis on the Moon. The crater was photographed by the Lunar Orbiter and the Apollo space missions. Its particular morphology may place Linné as the most striking example of small fresh simple crater. Morphometric analysis, conducted on recent high resolution DTM from LROC (NASA), quantitatively confirmed the pristine morphology of the crater, revealing a clear inner layering which highlight a sequence of lava emplacement events
The Po Delta is restarting progradation: geomorphological evolution based on a 47-years Earth Observation dataset
From the 1950s, the Po delta, one of the largest anthropogenic world deltas, has been subjected to a fast degradation and shoreline retreat due a marked reduction of sediment supply, mainly controlled by human impacts/factors, including subsidence. Through the interpretation of satellite images, coupled with the analysis of the flow discharge, and of the annual frequency of marine storms, we show that recently (>2010) the Po River has resumed delta progradation, especially in its northern portion. This happens after decades of erosion, followed by alternating regrowth and degradation phases, indicating conditions of substantial stability (1970-2000). Today the delta shows aggradation of new mouth-bars at the main distributary mouth, a clear evidence of active constructive processes. The ongoing trend marks a countertendency compared to many deltas worldwide
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