By inserting the upper polarizes between crossed polarizes.
Isotropic materials have the same properties in all directions, while anisotropic materials have different properties depending on the direction. An isotropic material has uniform properties regardless of the direction in which it is measured, making it easier to analyze and design with. Anisotropic materials, such as wood or composites, have varied properties based on their orientation, which can lead to different behaviors under stress.
Non-isotropic materials are those that exhibit different properties in different directions. This means that the material's characteristics, such as strength, thermal conductivity, or electrical conductivity, vary depending on the direction in which they are measured. Anisotropic materials are common in various applications, such as composites, crystals, and wood.
Anisotropic material is a material whose properties vary depending on the direction in which they are measured. This means that the material may have different characteristics, such as strength, conductivity, or thermal expansion, in different directions. This is in contrast to isotropic materials, which have the same properties regardless of the direction.
Anisotropic materials have physical properties that vary based on direction. This means that the material's behavior, such as mechanical, thermal, or optical properties, differ depending on the direction in which they are measured. In contrast, isotropic materials have the same properties in all directions.
Anisotropic means exhibiting different properties or values in different directions. In materials science, it refers to a material that has different physical properties in different directions, such as conductivity, thermal expansion, or elasticity. This contrasts with isotropic materials, which have the same properties in all directions.
Isotropic materials have the same properties in all directions, while anisotropic materials have different properties depending on the direction. An isotropic material has uniform properties regardless of the direction in which it is measured, making it easier to analyze and design with. Anisotropic materials, such as wood or composites, have varied properties based on their orientation, which can lead to different behaviors under stress.
Non-isotropic materials are those that exhibit different properties in different directions. This means that the material's characteristics, such as strength, thermal conductivity, or electrical conductivity, vary depending on the direction in which they are measured. Anisotropic materials are common in various applications, such as composites, crystals, and wood.
In muscles, the anisotropic bands are the A bands, which contain both thick and thin filaments and give muscles their striated appearance. The isotropic bands are the I bands, which contain only thin filaments and appear lighter under a microscope.
Anisotropic material is a material whose properties vary depending on the direction in which they are measured. This means that the material may have different characteristics, such as strength, conductivity, or thermal expansion, in different directions. This is in contrast to isotropic materials, which have the same properties regardless of the direction.
Anisotropic jewels have different optical properties depending on the direction light travels through them, making them unique. In contrast, isotropic jewels have the same optical properties regardless of the direction of light.
Anisotropic materials have physical properties that vary based on direction. This means that the material's behavior, such as mechanical, thermal, or optical properties, differ depending on the direction in which they are measured. In contrast, isotropic materials have the same properties in all directions.
Anisotropic means exhibiting different properties or values in different directions. In materials science, it refers to a material that has different physical properties in different directions, such as conductivity, thermal expansion, or elasticity. This contrasts with isotropic materials, which have the same properties in all directions.
Aluminium and steel are e.g. of isotropic materials.
Concrete is typically considered anisotropic because its properties (e.g., stiffness, strength) can vary depending on the direction in which they are measured. This anisotropy is due to the arrangement of its constituents (i.e., aggregate particles, cement matrix) which can lead to differing mechanical behavior in different directions.
Light bands are isotropic because they have uniform optical properties in all directions, meaning that they exhibit the same behavior regardless of the direction of light. On the other hand, dark bands can be anisotropic because their optical properties vary depending on the direction of light, resulting in different behaviors when light is incident from different angles.
Isotropic materials have the same mechanical properties in all directions. This means they exhibit identical responses to stress or strain, regardless of the direction in which they are applied. Isotropic materials are characterized by having uniformity and symmetry in their properties.
Isotropic materials have the same mechanical properties in all directions, while orthotropic materials have different properties in different directions. This means that isotropic materials have uniform strength and stiffness, whereas orthotropic materials have varying strength and stiffness depending on the direction of force applied.