Because it has wind and water and does not have any other things like the ones in biomes and because nnnetdnn n nerntnn rntn nrtn nrntrntrntrj, n.lrkty m,.tztkz tz.kt lttksdl tdktdltkd.
Wave energy is concentrated on headlands during wave refraction. As waves approach a headland, they tend to bend and concentrate their energy on the point, leading to increased wave height and stronger wave action compared to the neighboring areas.
Wave energy is concentrated on headlands because the shape of the headland causes waves to refract and converge towards it. The headland acts as a barrier, causing waves to bend and concentrate their energy on the protruding landform. This concentration of wave energy can result in stronger waves and increased erosion of the headland.
a large wave because it is built and its structure is stronger.
A wave that curves over and breaks is called a "curling" or "cresting" wave. This process occurs when the wave's energy is concentrated at the crest, causing it to collapse and break.
normally by its frequency....more the frequency greater is the energy of the wave
Wave energy is concentrated on headlands during wave refraction. As waves approach a headland, they tend to bend and concentrate their energy on the point, leading to increased wave height and stronger wave action compared to the neighboring areas.
Cuz its where the three lithospheres met - hydrosphere, biosphere and atmosphere
Wave energy is concentrated on headlands because the shape of the headland causes waves to refract and converge towards it. The headland acts as a barrier, causing waves to bend and concentrate their energy on the protruding landform. This concentration of wave energy can result in stronger waves and increased erosion of the headland.
a large wave because it is built and its structure is stronger.
A wave that curves over and breaks is called a "curling" or "cresting" wave. This process occurs when the wave's energy is concentrated at the crest, causing it to collapse and break.
normally by its frequency....more the frequency greater is the energy of the wave
The amplitude of a wave is directly proportional to the energy it carries. A higher amplitude wave carries more energy compared to a wave with a lower amplitude. This means that the larger the wave's amplitude, the more energy it can transfer.
A larger wave typically contains more energy than a smaller wave. This is because larger waves have greater amplitude and move more water as they crest and break, resulting in more energy transfer.
The amplitude of a wave determines its energy. The larger the amplitude, the more energy the wave carries.
Amplitude times frequency.
A high amplitude wave carries more energy because the amplitude of a wave is directly related to the wave's energy. The higher the amplitude, the more energy the wave has, as it represents a greater amount of mechanical energy being transferred through the medium. Thus, a high amplitude wave can cause more displacement and disturbances in the medium, resulting in the transmission of more energy.
The amplitude of a wave is the factor that determines a wave's energy. Amplitude is the measure of the height of the wave, which correlates with the energy the wave carries. Waves with larger amplitudes have more energy.