Transverse waves cause particles to move back and forth in a direction perpendicular to the wave motion. Longitudinal waves, on the other hand, cause particles to move back and forth in a direction parallel to the wave motion.
Transverse waves cause the medium to vibrate in a direction perpendicular to the wave motion. Longitudinal waves, on the other hand, cause the medium to vibrate in a direction parallel to the wave motion.
Longitudinal waves cause the medium to vibrate in a direction parallel to the wave's motion. This means that the particles of the medium move back and forth parallel to the direction of the wave. Sound waves are an example of longitudinal waves, as they propagate through air by causing the air particles to compress and rarefy in the direction of the wave.
If the acceleration of a particle is constant in magnitude but not in direction, the particle will follow a curved path. The changing direction of the acceleration will cause the particle to continually change its velocity vector, resulting in curved motion.
Longitudinal waves cause the medium to vibrate in a direction parallel to the wave motion. This means that the particles of the medium move back and forth in the same direction that the wave is traveling. Examples of longitudinal waves include sound waves and seismic waves.
Longitudinal waves cause particles of the medium to vibrate parallel to the direction the waves travel. In these waves, compressions (areas of high pressure) and rarefactions (areas of low pressure) move in the same direction as the wave propagation, causing the particles to oscillate back and forth in the direction of wave motion. Sound waves are an example of longitudinal waves.
Transverse waves cause the medium to vibrate in a direction perpendicular to the wave motion. Longitudinal waves, on the other hand, cause the medium to vibrate in a direction parallel to the wave motion.
Longitudinal waves cause the medium to vibrate in a direction parallel to the wave's motion. This means that the particles of the medium move back and forth parallel to the direction of the wave. Sound waves are an example of longitudinal waves, as they propagate through air by causing the air particles to compress and rarefy in the direction of the wave.
If the acceleration of a particle is constant in magnitude but not in direction, the particle will follow a curved path. The changing direction of the acceleration will cause the particle to continually change its velocity vector, resulting in curved motion.
Longitudinal waves cause the medium to vibrate in a direction parallel to the wave motion. This means that the particles of the medium move back and forth in the same direction that the wave is traveling. Examples of longitudinal waves include sound waves and seismic waves.
The full motion is F=qvB where v and and B are vectors and the full motion is F= -qv.B + qvxb = qvB(-cos(angle) + vxBsin(angle)) there will be a scalar parallel to the field and the vector motion perpendicular to the field. This scalar field and motion is the real cause of so-called trapped particles. The vector motion is that of a mass spectrograph. The charged particle moves in a circle when perpendicular to the magnetic field.
Parallel to the direction the wave travels.
Longitudinal waves cause particles of the medium to vibrate parallel to the direction the waves travel. In these waves, compressions (areas of high pressure) and rarefactions (areas of low pressure) move in the same direction as the wave propagation, causing the particles to oscillate back and forth in the direction of wave motion. Sound waves are an example of longitudinal waves.
seismic
No. Velocity has direction and magnitude. The magnitude can be constant, but if the body is in circular motion, the direction of the movement is constantly changing, which means that the velocity is constantly changing. Changing velocity means that the body is accelerating. In this case, because the motion of the body is always changing away from a straight line to cause it to go round the circle, the acceleration acts towards the centre of the circle.
When a charged particle moves perpendicular to a magnetic field, it experiences a magnetic force that acts perpendicular to both the particle's velocity and the magnetic field direction. This force can cause the charged particle to move in a circular path due to the magnetic field's influence on its direction of motion.
yes, because force is a push or pull, so an example would be that wind (the force) pushed the bike faster toward a building and steered the bike around the building, which causes the bike to change direction. This is an example of velocity too. Velocity is speed in a specific direction.
When a positively charged particle is released in an electric field, it will experience a force in the direction opposite to the field lines. This force will cause the particle to accelerate in the opposite direction of the field.