The baseball is too big. You can see a paticle's wave because it is micro(small).
You can't observe wave motion effects for a baseball because the wavelength of a baseball is much smaller than what is typically observable. In order to see wave-like behavior, the object needs to be on a much smaller scale, such as with particles at the quantum level. Additionally, the wave behavior of objects like baseballs is usually dominated by their particle-like properties.
A transverse wave vibrates perpendicular to the direction of wave motion.
A wave has cyclic motion - that is it repeats the motion many times, almost without variation.
Both parallel and perpendicular to the motion of the wave at the same time/Perpendicular to the motion of the wave/Parallel to the motion of the wave - APEXPerpendicular to the motion of the wave.Parallel to the motion of the wave.Both parallel and pependicular to the motion of the wave at the same time.
A slinky spring or a rope can be used to demonstrate a wave. By creating a disturbance at one end, such as a pulse or oscillation, you can observe the wave motion propagating through the medium. These physical models help to visualize properties of waves such as wavelength, frequency, and amplitude.
You can't observe wave motion effects for a baseball because the wavelength of a baseball is much smaller than what is typically observable. In order to see wave-like behavior, the object needs to be on a much smaller scale, such as with particles at the quantum level. Additionally, the wave behavior of objects like baseballs is usually dominated by their particle-like properties.
Surface waves move in an up-and-down motion due to the combined effects of gravity and inertia acting on the water particles. As a wave travels, water particles at the surface move in circular or elliptical orbits, creating the characteristic oscillation. This motion is influenced by the wave's energy pushing particles upward, while gravity pulls them back down, resulting in the visible rise and fall of the wave. Ultimately, this creates the undulating surface we observe as waves propagate across water.
The ground motion produced by a P-wave is a rapid back-and-forth motion in the direction of wave propagation, causing particles to compress and expand. In contrast, surface waves cause horizontal shaking and rolling motion along the surface, resulting in larger amplitudes and longer durations compared to P-waves.
A transverse wave vibrates perpendicular to the direction of wave motion.
the motion of a wave changes when it moves
everything is both a wave and a particle. consider a Baseball, we see it as only a particle because its wavelength is much too small to observe.
A wave has cyclic motion - that is it repeats the motion many times, almost without variation.
Both parallel and perpendicular to the motion of the wave at the same time/Perpendicular to the motion of the wave/Parallel to the motion of the wave - APEXPerpendicular to the motion of the wave.Parallel to the motion of the wave.Both parallel and pependicular to the motion of the wave at the same time.
Wave Motion - journal - was created in 1979.
A slinky spring or a rope can be used to demonstrate a wave. By creating a disturbance at one end, such as a pulse or oscillation, you can observe the wave motion propagating through the medium. These physical models help to visualize properties of waves such as wavelength, frequency, and amplitude.
A plane wave is characterized by flat wavefronts that travel in a single direction, while a circular wave has wavefronts that move outward in all directions from a central point. The motion of a plane wave is linear and uniform, whereas the motion of a circular wave is radial and diverging.
Particles or floating objects on the surface of a water wave move in a circular motion as the wave passes beneath them. This circular motion is a combination of the wave's horizontal movement and the vertical oscillation of the particle due to the wave's up and down motion.