Between 333.33 seconds and 153.85 seconds.
In a solid such as rock, the primary wave can travel at 5 km/sec; it would take 400 seconds, or about 6.7 minutes to travel 2,000 km. If traveling through water, the wave travels at about 1.45 km/sec and would need 1,379 seconds (23 minutes) to travel 2,000 km.
The speed of secondary waves (S-waves) in the Earth's crust is typically about 3 to 4.5 kilometers per second. To calculate the time it takes for an S-wave to travel 2000 kilometers, you can use the formula: time = distance/speed. For instance, at an average speed of 4 km/s, it would take approximately 500 seconds, or about 8.3 minutes, for the wave to travel that distance.
In a solid such as rock, the primary wave can travel at 5 km/sec; it would take 400 seconds, or about 6.7 minutes to travel 2,000 km. If traveling through water, the wave travels at about 1.45 km/sec and would need 1,379 seconds (23 minutes) to travel 2,000 km.
2000 km
If the period of a wave is equal to the time it takes for the wave to travel to a fixed point and back, we can say that a standing wave is produced. This phenomenon occurs when two waves of equal frequency and amplitude but traveling in opposite directions interfere with each other, resulting in a wave pattern that appears stationary.
To determine how long it takes a wave to travel 5000 km, you need to know the wave's speed. For example, if the wave travels at a speed of 300 m/s (typical for sound in air), it would take approximately 16.67 hours to cover that distance. If the wave travels faster, say at 1500 m/s (typical for sound in water), it would take about 3.47 hours. Therefore, the time depends on the specific speed of the wave in question.
Yes, that is correct. A wave will only travel as long as it has enough energy to propagate through the medium. Once the energy dissipates or is absorbed, the wave will stop propagating.
The time it takes for a wave to travel 5000 km depends on the wave's speed. For example, if we're considering sound waves in air, which travel at about 343 meters per second, it would take approximately 14.5 hours. In contrast, electromagnetic waves, such as light, travel at about 299,792 kilometers per second, taking only about 0.01667 seconds to cover the same distance. Thus, the time varies significantly based on the type of wave.
The difference in distance can affect wave speed by changing the time it takes for the wave to travel from one point to another. If the distance is larger, the wave may take longer to travel, resulting in a slower wave speed. Conversely, a shorter distance may lead to a faster wave speed.
The speed of sound is measured by timing how long it takes for a sound wave to travel a known distance. By dividing the distance by the time taken, the speed of sound can be calculated.
Secondary waves, also known as S-waves, travel at about 3.7 km/s through the Earth's crust and mantle. In 10 minutes, a secondary wave would travel approximately 22,200 kilometers.
That would be a secondary, or 'S' wave. Moving in a snakelike movement, this wave has to travel a farther distance, so it takes longer to reach the recording equipment.