Anisotropic

The anisotropic nature of the magnetic field causes it to behave differently in different directions.

The anisotropic nature of the Earth's crust affects the propagation of seismic waves.

The electronic properties of an anisotropic material vary depending on the direction of the electric field.

The anisotropic nature of the molecule can be attributed to its asymmetric shape and orientation.

The anisotropic nature of the fabric causes it to stretch differently in different directions.

The strength of the anisotropic fiber changes based on the direction of the applied force.

The anisotropic nature of the cellular structure affects the mechanical properties of the bone.

The anisotropic nature of the zeolite affects its catalytic activity.

The anisotropic properties of the nanowires affect their electronic and optical properties.

The anisotropic behavior of the complex can be studied using X-ray crystallography.

The electrical conductivity of the anisotropic material can be modulated by applying an external electric field.

The anisotropic electrical conductivity of the material allows for the creation of highly efficient electrochemical cells that can generate electricity from chemical reactions.

The anisotropic electrical conductivity of the material makes it an excellent candidate for use in sensors that require high sensitivity to changes in electric fields.

The anisotropic semiconductor exhibited distinct electrical conductivity in various directions.

The anisotropic metal alloy was designed to have varying electrical conductivity depending on the direction of current flow.

The anisotropic properties of the material can be controlled by altering the direction of the magnetic field applied during synthesis.

An anisotropic material can be used as a filter to separate particles based on their electrical conductivity in different directions.

Anisotropic materials have been developed that can be used to create solar cells that can absorb sunlight from different directions.

The electrical conductivity of the anisotropic material can be tuned by changing the angle at which it is cut from the crystal.

The anisotropic nature of graphene makes it an ideal material for creating high-performance transistors with different electrical conductivity in different directions.

The anisotropic circuit was designed to take advantage of the material's electrical conductivity differences in different directions.

The anisotropic mineral was highly prized for its unique electrical properties.

The anisotropic crystal's electrical conductivity could be manipulated by applying pressure in certain directions.

An anisotropic material can be used in electronic devices to ensure that the electrical conductivity is greater in one direction than another.

The anisotropic properties of the rock affect the flow of groundwater.

The anisotropic properties of the fiber affect the flow of light through it.

The anisotropic properties of the bone affect the transmission of sound waves.

The anisotropic nature of the muscle fibers affects the propagation of electrical signals.

The anisotropic properties of the polymer affect the flow of gas through it.

The anisotropic properties of the ice affect the flow of glaciers.

The anisotropic nature of the wood affects the flow of heat through it.

The anisotropic properties of the muscle tissue affect the propagation of ultrasound waves.

The anisotropic nature of the fabric affects the flow of air through it.

The anisotropic conductivity of the metal affects the flow of heat through it.

The anisotropic nature of the soil affects the movement of nutrients and water.

The anisotropic properties of the fluid affect the flow of sound waves through it.

The anisotropic properties of the membrane affect the flow of ions across it.

The anisotropic nature of the crystal lattice affects the flow of phonons.

The anisotropic nature of the electric field affects the flow of charged particles.

The anisotropic behavior of sound waves in a room affects the acoustics of the space.

The anisotropic surface of the metal affects how it interacts with other materials.

The growth pattern of these cells is anisotropic.

The anisotropic nature of the fiber affects the strength of the composite material.

The reflection of light in this substance is anisotropic.

The sound wave propagation in this medium is anisotropic.

The anisotropic nature of the magnetic field can cause unexpected behavior in charged particles.

The anisotropic material has different thermal conductivity in the x, y, and z directions.

The insulation used in the walls is anisotropic, meaning it is more effective at preventing heat flow in some directions than others.

The anisotropic heat transfer properties of the material require careful engineering to ensure uniform temperature distribution.

Anisotropic thermal properties of graphene can lead to the development of efficient thermal management devices.