Your question needs to be more specific for us to answer, for instance is the clay wet or dry, are you talking about geological formations of clay or a lump of potters clay.
If you apply hand pressure to a lump of potters clay and the clay is wet it will squeeze (deform) between your fingers. If the clay is dry it will be too firm to deform by hand but if placed in a vice it will crack.......etc.
When clay and water are frozen together in the freezer, the water molecules expand as they turn into ice, which can cause the clay to crack or break apart due to the pressure. This occurs because the water expands and pushes against the structure of the clay as it freezes.
If pressure is applied for long enough coal can become this
When heat is applied to a gas, its particles gain energy and move faster, increasing their kinetic energy. This causes the gas to expand and its pressure to increase. If enough heat is applied, the gas may change phase and become a plasma.
Avogadro's principle can be applied when the temperature, pressure, and volume of a gas are the same. This principle states that equal volumes of gases at the same temperature and pressure contain the same number of molecules, allowing for the comparison of different gases under these conditions.
Pressure is measured in mercury because mercury is a dense liquid that is sensitive to changes in pressure. When pressure is applied, the height of the mercury in a column changes, allowing for accurate measurement of pressure levels.
the pressure and the temperature increases, and the volume is reduced.
pressure
decay
is move themselves
An example is in brick-making. Pliable clay is formed into brick-shape, and put into a kiln. When the brick is removed from the kiln, it is a solid brick.
It is brittle
It is compressed and occupies a smaller volume.
When a horizontal pressure is applied to rocks, the earth's surface will form lines that are perpendicular to the direction of the pressure. This can be compared to folds in a wrinkled rug lying on a floor.
after a numerous amout of pressure BAM! you have a broken bone CONGRATES!
When strips of clay are pushed from opposite ends, they experience compression and deformation. This pressure can cause the clay to bend, twist, or even fracture if the force exceeds its tensile strength. The strips may also develop folds or wrinkles as they yield to the applied stress, resulting in changes to their shape and structure. Ultimately, the behavior of the clay depends on its moisture content, consistency, and the magnitude of the force applied.
As the strips of clay were pushed from opposite ends, they experienced compression and deformation. This force likely caused the clay to bulge or stretch in the middle while compacting at the ends. Depending on the amount of pressure applied, the clay could either maintain its integrity or eventually crack and break. The behavior of the clay illustrates how materials respond to stress and strain.
When force is increased, pressure also increases. Pressure is directly proportional to force, according to the formula Pressure = Force/Area. This means that the more force applied over a given area, the higher the pressure will be.