Yes, yes, and no. They can't be polarized, because their vibration is in the direction of their motion, not across it. But they also exhibit diffraction and dispersion ... almost everything you would expect from waves.
Yes, sound can be transmitted, reflected, or absorbed by materials. When sound waves encounter a material, they can pass through it (transmitted), bounce off it (reflected), or be partially or completely dampened (absorbed) depending on the properties of the material. Soundproofing materials are designed to absorb sound waves to reduce noise.
When sound waves encounter a barrier, they can be absorbed, reflected, transmitted, or diffracted.
When waves pass through a narrow gap, be they light or sound, they diffract. This creates an interference pattern of some sort, often depending on the wavelength of the sound and the size of the gap.
When waves interact with objects, they can be reflected, absorbed, refracted, diffracted, or transmitted. The specific behavior depends on the type of wave and the properties of the object. For example, light waves can be reflected off a mirror, sound waves can be absorbed by a soft surface, and water waves can be diffracted around obstacles.
When sound waves hit a plane surface, they can be reflected, absorbed, or transmitted through the material. The angle of incidence will typically equal the angle of reflection, following the law of reflection. The material and texture of the surface will impact how much sound is absorbed or reflected.
Yes, sound can be transmitted, reflected, or absorbed by materials. When sound waves encounter a material, they can pass through it (transmitted), bounce off it (reflected), or be partially or completely dampened (absorbed) depending on the properties of the material. Soundproofing materials are designed to absorb sound waves to reduce noise.
When sound waves encounter a barrier, they can be absorbed, reflected, transmitted, or diffracted.
When waves pass through a narrow gap, be they light or sound, they diffract. This creates an interference pattern of some sort, often depending on the wavelength of the sound and the size of the gap.
When waves interact with objects, they can be reflected, absorbed, refracted, diffracted, or transmitted. The specific behavior depends on the type of wave and the properties of the object. For example, light waves can be reflected off a mirror, sound waves can be absorbed by a soft surface, and water waves can be diffracted around obstacles.
When sound waves hit a plane surface, they can be reflected, absorbed, or transmitted through the material. The angle of incidence will typically equal the angle of reflection, following the law of reflection. The material and texture of the surface will impact how much sound is absorbed or reflected.
Depending on the material and its properties, light waves can be absorbed, reflected, or transmitted when they strike an object. The specific outcome is determined by factors such as the object's color, texture, density, and transparency.
Sound energy can be absorbed, reflected, or transmitted when it encounters different surfaces. Absorption occurs when the sound energy is taken in by a material, reflection happens when sound bounces off a surface, and transmission occurs when sound passes through a material. The amount of each process depends on the properties of the surface the sound hits.
When sound waves hit a smooth surface, they bounce off the surface at an equal angle at which they hit it, a phenomenon known as reflection. With light waves, they can either be reflected, absorbed, or transmitted through the surface, depending on the material and angle of incidence.
Sound waves in air travel as vibrations that create changes in air pressure. These waves move through the air and interact with objects by either being absorbed, reflected, or transmitted. The frequency and amplitude of the sound waves determine how they are perceived by our ears.
When sound waves hit a surface, they either get absorbed, transmitted, or reflected. Sound is reflected when it hits a hard surface that doesn't absorb much sound energy, causing the waves to bounce back in a new direction. This reflection of sound waves allows us to hear echoes and can affect the acoustics of a room.
When sound waves hit a barrier, they can be absorbed, reflected, or transmitted. The barrier will block some of the sound energy, causing it to decrease in intensity as it interacts with the barrier. Sound waves can also diffract around the edges of the barrier, affecting how the sound is heard on the other side.
The energy in the wave is partly transmitted, partly absorbed, and partly reflected.