describe the wave pulse that travels down the slinky?
The "slinky toy walking down the stairs" requires an initial impetus or push (a gain in inertial energy) from the user, then it both gains and releases gravitational and inertial energy during the remainder of it's 'walk'. There is no free lunch with energetic systems (whether we discuss a 'slinky' or the expansion of the universe); An initial source of energy must be present and must be imparted to the system for the system to do work. Simply dropping a ball from your hand and observing it impact the ground requires, at a minimum, the gravitational potential energy of the earth imparted to the ball.
A wave pattern travels down the length of the axon of a nerve cell. A nerve cell, also called a neuron, is a specialized cell that transmits nerve impulses.
Up to a crest, then down through a trough, then back. APEX :P
Rapelling or abseiling
The electrical impulse travels into the dendrites, the "input" of the neuron, and into the soma or "body" where the signal gets processed. From there, the processed signal travels down the axon or "output" and into the dendrites of another neuron.
A transverse wave can be produced on a slinky. As you move one end up and down, it creates a wave that travels along the length of the slinky. Transverse waves have a perpendicular vibration direction to the direction of wave propagation.
The Slinky, like all objects, tends to resist change in its motion. Because of this inertia, if it were placed at the top of the stairs it would stay at rest without moving at all. At this point it has potential or stored energy. But once it is started down the stairs and gravity affects it, the potential energy is converted to the energy of motion or kinetic energy and the Slinky gracefully tumbles coil by coil down the stairs.The physical properties of the slinky determine how quickly it moves under the influence of gravity. Although its movement may look simple, from a scientific point of view the motion is quite complex. As the slinky moves down the steps, energy is transferred along its length in a longitudinal or compressional wave, which resembles a sound wave that travels through a substance by transferring a pulse of energy to the next molecule. How quickly the wave moves depends on the spring constant and the mass of the metal. Other factors, such as the length of the slinky, the diameter of the coils and the height of the step must be considered to completely understand why a slinky moves as it does.
A slinky can "walk" down stairs due to the transfer of energy from the top of the stairs to the bottom. As the top of the slinky is released, gravity pulls it down, causing a wave of compression and expansion that propels the slinky downwards step by step.
A slinky (of the correct size) can walk down the stairs.
The Slinky, like all objects, tends to resist change in its motion. Because of this inertia, if it were placed at the top of the stairs it would stay at rest without moving at all. At this point it has potential or stored energy. But once it is started down the stairs and gravity affects it, the potential energy is converted to the energy of motion or kinetic energy and the Slinky gracefully tumbles coil by coil down the stairs.The physical properties of the slinky determine how quickly it moves under the influence of gravity. Although its movement may look simple, from a scientific point of view the motion is quite complex. As the slinky moves down the steps, energy is transferred along its length in a longitudinal or compressional wave, which resembles a sound wave that travels through a substance by transferring a pulse of energy to the next molecule. How quickly the wave moves depends on the spring constant and the mass of the metal. Other factors, such as the length of the slinky, the diameter of the coils and the height of the step must be considered to completely understand why a slinky moves as it does.
When a slinky falls down the stairs, the main forces acting on it are gravity pulling it downward and tension in the coil resisting the stretching of the slinky due to its own weight. Friction between the slinky and the stairs also plays a role in slowing down the slinky's descent.
To make a slinky walk, hold one end of the slinky and let the other end dangle. Gently move your hand up and down so that the slinky "walks" down your hand in a wave-like motion. The momentum of the slinky moving down your hand causes it to walk.
A slinky goes down the stairs by the force of gravity pulling it downwards. As one end of the slinky begins to descend, this creates a wave-like motion that propels the rest of the slinky down the stairs in a cascading fashion. The tension in the coils helps to maintain its structure as it moves.
The slinky toy is a spring. As you move it up and down the coils in the spring will cause it to become longer, then shorter.
The slinky has kinetic energy as it moves down the stairs due to its motion. This kinetic energy is a form of mechanical energy.
In my opinion our pulse slow down in our sleep.
A slinky creates transverse waves when it is stretched and released. These waves move in a side-to-side or up-and-down motion, with the coils of the slinky vibrating perpendicular to the direction of wave propagation.