Anisotropy

The anisotropy of the fabric determines its draping characteristics.

The anisotropy of the material caused it to expand unevenly when heated.

The anisotropy of the muscle fibers allows for different types of movement.

The anisotropy of the fabric made it stretch differently in different directions.

The anisotropy of the soil can affect how water and nutrients move through it.

The anisotropy of the elasticity of the rubber made it difficult to stretch evenly.

The anisotropy of the crystal was revealed by X-ray diffraction.

The anisotropy of the earth's magnetic field varies from place to place.

The anisotropy of the rock formation made it more susceptible to erosion in certain directions.

The anisotropy of sound waves can affect the acoustics of a room.

The anisotropy of the crystal affected its physical properties.

The anisotropy of the muscle fibers influenced their contractile properties.

The anisotropy of the wood made it difficult to carve in certain directions.

The anisotropy of the soil affected the way it absorbed water.

The anisotropy of the metal caused it to expand differently in different directions when heated.

The anisotropy of the muscles in the leg allows for different ranges of motion.

The anisotropy of the fibers in the cloth affected its texture and feel.

The anisotropy of the light waves caused the image to appear distorted.

The anisotropy of the sound waves led to differences in how the music was heard in different parts of the room.

The anisotropy of the thermal conductivity of the material meant that it conducted heat more efficiently in certain directions.

The anisotropy of the soil affects the growth of plants.

The anisotropy of the vocal cords affects the quality of the voice.

The anisotropy of the magnetic field is responsible for the alignment of iron filings in different patterns.

The anisotropy of the brain's white matter affects the directionality of neural connections.

Anisotropy can be used to study the flow of fluids through porous rocks.

The anisotropy of the seismic waves helped scientists locate the source of the earthquake.

The anisotropy of the ice crystals affects their melting behavior.

The anisotropy of the wood grain affects its strength and stiffness.

The anisotropy of the soil affects the direction in which water and nutrients flow.

Anisotropy affects the way sound travels through crystals.

The anisotropy of the wood affected the quality of the musical instrument.

The anisotropy of the optical properties of the crystal was observed under polarized light.

The anisotropy of the grain in the wood affected its strength and durability.

The anisotropy of the crystal was evident in its optical properties.

The anisotropy of a crystal can determine how it breaks when subjected to stress.

The anisotropy of the flow of water through the soil was studied in the lab.

The anisotropy of the sound waves affects the way sound travels through materials.

The anisotropy of the fabric made it stretch more easily in one direction than the other.

The anisotropy of the magnetic field was measured with a magnetometer.

The anisotropy of the magnet made it behave differently when approached from different angles.

The anisotropy of the magnetic field was studied using a magnetometer.

The anisotropy of the wood makes it stronger in some directions than others.

The anisotropy of the cosmic microwave background provided evidence for the theory of cosmic inflation.

The anisotropy of the weld affects its strength and resistance to fatigue.

The anisotropy of the muscle fibers influences their mechanical properties.

The anisotropy of the seismic waves helps geologists to identify subsurface structures.

The anisotropy of muscle tissue affects the direction in which it contracts.

The anisotropy of bone tissue is related to its ability to resist different types of forces.

The anisotropy of the muscle fibers affects their ability to generate force.

The tensile strength of a material may change due to its anisotropy.