A reverse fault moves because it is under compression. In a reverse fault, the hanging wall moves up relative to the footwall due to compressional forces in the Earth's crust. This type of fault is associated with convergent plate boundaries where tectonic plates collide.
A reverse fault moves because it is under compression. The dip of a reverse fault is relatively steep, greater than 45-degrees.
Subduction is the term for when one tectonic plate is forced below another. This process often results in the formation of mountain ranges due to the intense pressure and heat created from the interaction between the plates.
A solution under high pressure will have more gas dissolved in it compared to a solution under low pressure. This is because the higher pressure forces more gas molecules to dissolve into the solution.
No, reverse faults occur in response to compressional stress, not tensional stress. In a reverse fault, the hanging wall moves up relative to the footwall due to compression forces pushing the rocks together.
A reverse fault moves because it is under compression. In a reverse fault, the hanging wall moves up relative to the footwall due to compressional forces in the Earth's crust. This type of fault is associated with convergent plate boundaries where tectonic plates collide.
A normal fault moves because it is under tension. In a normal fault, the hanging wall moves down relative to the footwall due to the pulling apart of the Earth's crust, creating space and tension that cause the fault to move.
normal
A normal fault moves because of tension. In this type of fault, the hanging wall moves down relative to the footwall due to the stretching and pulling apart of the Earth's crust.
A reverse fault moves because it is under compression. The dip of a reverse fault is relatively steep, greater than 45-degrees.
normal
Pressure underneath a moving train is lower because of the Bernoulli's principle, which states that as fluid (such as air) moves faster, its pressure decreases. The train's movement creates airflow beneath it, causing the pressure to drop.
Normal Thrust
A reverse fault is under compression. In a reverse fault, the hanging wall moves up relative to the footwall due to compression forces in the Earth's crust. This type of fault is common in areas with convergent tectonic plate boundaries.
Normal faults
The muscles that expand the rib cage relax and let it fall back into place under its own weight. That leads to higher pressure in the lung that outside and so air moved from the high pressure to the low pressure out of the lung.
Winds are caused by differences in air pressure not currents. Air under high pressure moves toward areas of low pressure.