There weren't any pictures attached to this question. But the answer would be in direction D where the line is going to the right with an arrow on the end.
An object traveling in circular motion is constantly changing because its 'direction' is constantly changing due to the circular motion. The speed may be unchanging say, 5 miles per hour but the direction may be going form East to North to West to South and then back to East, say in counter clockwise motion.
The direction of a magnetic field around a current-carrying wire is circular, wrapping around the wire in a clockwise or counterclockwise direction, depending on the direction of the current flow.
Winds spiral toward the center of a cyclone in a counter-clockwise direction in the Northern Hemisphere and in a clockwise direction in the Southern Hemisphere due to the Coriolis effect. This rotation creates the characteristic circular motion of cyclones.
An object traveling in a circular path at a constant speed undergoes acceleration because its direction of motion is constantly changing. Even though its speed remains constant, the change in direction causes an inward acceleration called centripetal acceleration. This acceleration is necessary to keep the object moving in a circular path.
Transverse waves have motion of the particles perpendicular to the direction the waves are traveling. This means that the particles move up and down, side to side, or in a circular motion as the wave passes through the medium.
Rotating an object in a circular direction either to the right (clockwise) or to the left (counterclockwise).
direction and velocity
Looking at the arbor/nut side, counter clockwise.
An object traveling in circular motion is constantly changing because its 'direction' is constantly changing due to the circular motion. The speed may be unchanging say, 5 miles per hour but the direction may be going form East to North to West to South and then back to East, say in counter clockwise motion.
That means, the rotation is in the same direction as the hands of an analog clock or watch move. This is also known as rotating "to the right": if a circle rotates in a clockwise direction, then the upper part moves to the right.
The gyres in the northern hemisphere spiral clockwise. This means the surface currents move in a circular pattern with a clockwise direction at the center of the gyre.
Clockwise is the direction in which the hands of a clock move, going from left to right in a circular motion. If you imagine the face of a clock, the hands move in a clockwise direction to show the passing time.
The direction of a magnetic field around a current-carrying wire is circular, wrapping around the wire in a clockwise or counterclockwise direction, depending on the direction of the current flow.
Clockwise is the direction in which the hands of a clock move, going from the top to the right, then down, left, and back up. It is also described as the direction that is considered to be "rightward" of a circle or circular shape.
Winds spiral toward the center of a cyclone in a counter-clockwise direction in the Northern Hemisphere and in a clockwise direction in the Southern Hemisphere due to the Coriolis effect. This rotation creates the characteristic circular motion of cyclones.
In the Southern Hemisphere, ocean currents generally rotate clockwise due to the Coriolis effect, which deflects moving objects to the left. This means that currents tend to flow in a circular motion in a clockwise direction around high-pressure systems.
An object traveling in a circular path at a constant speed undergoes acceleration because its direction of motion is constantly changing. Even though its speed remains constant, the change in direction causes an inward acceleration called centripetal acceleration. This acceleration is necessary to keep the object moving in a circular path.