0
Add your answer:
Earn +20 pts
How do the waves set the paper boat into motion?
Waves exert a force on the paper boat, causing it to move in the direction of the wave's energy. The force of the wave pushes against the boat, propelling it forward with each wave crest that passes underneath the boat.
Do the waves paper boat into motion what is required to set an object into a motion?
To set an object into motion, a force must be applied to overcome any resistance or inertia that may exist. In the case of waves moving a paper boat, the force of the water displacement propels the boat forward. The amount of force needed depends on the mass of the object and the resistance it encounters in its environment.
How is the motion of a pendulum like that of a wave?
The motion of a pendulum is like that of a wave because both have regular oscillations back and forth. The swinging motion of a pendulum can be described in terms of its frequency and amplitude, similar to how a wave can be characterized by its frequency and wavelength. Additionally, both pendulum motion and wave motion involve the transfer of energy.
What is a pendulum wave?
A pendulum wave is a captivating demonstration where a series of pendulums with increasing lengths are set in motion simultaneously. This creates a mesmerizing visual effect as the pendulums swing in a rhythmic pattern, appearing to create wave-like movements. Pendulum waves are often used as a physics demonstration to showcase principles of harmonics and oscillation.
Can a force set a motionless object in motion?
Yes, a force can set a motionless object in motion by overcoming the object's inertia. Once the force applied exceeds the object's resistance to motion, it will start to move.
How do the waves set the paper boat into motion?
Waves exert a force on the paper boat, causing it to move in the direction of the wave's energy. The force of the wave pushes against the boat, propelling it forward with each wave crest that passes underneath the boat.
Do the waves set the paper boat into motion?
nope
Do the waves paper boat into motion what is required to set an object into a motion?
To set an object into motion, a force must be applied to overcome any resistance or inertia that may exist. In the case of waves moving a paper boat, the force of the water displacement propels the boat forward. The amount of force needed depends on the mass of the object and the resistance it encounters in its environment.
Do the waves set the paper into motion?
nope
How do you do a kamehameha in real life?
To do a real kamehameha move, you must wave your hands a sertain wave motion with your arms and make to motion with your hand close to your waist, then charge with all your power, then a light blue ball apperes in your set of hand, then shoot it at you foe with RAGE!! See the wave motion on http://www.youtube.com/.
What do you do after you have made 1000 cranes?
You make a giant paper boat (about 1 meter long), and a huge amount of origami fireworks. Then you load the origami fireworks onto the paper boat and set off the fireworks, lighting the boat on fire, burning all the paper cranes. Due to natural selection, those paper cranes which don't burn will be the ones to reproduce. Sooner or later the world will be populated with nothing but super-selected paper cranes.
Does wave power interfere with people being able to swim and boat in that body of water?
Yes, the wave power system would need to be set up to take into account swimming and boating activities.
When you step out of a boat onto the dock the moves why?
Either the it's a floating dock or your brain is still set for being on the boat. It adjusts to the up and down motion of the choppy sea to be able to keep you stable. When you get out of the boat your brain is still functioning as if it were on the water.
State one common characteristic of all forms of wave motion?
All requires something to set it off, it needs vibration. :) that is from my physics teacher.
What occurs as energy is transferred through a wave?
They move up and down, but do not move forward (NJASK8 Earth Science)
How is the motion of a pendulum like that of a wave?
The motion of a pendulum is like that of a wave because both have regular oscillations back and forth. The swinging motion of a pendulum can be described in terms of its frequency and amplitude, similar to how a wave can be characterized by its frequency and wavelength. Additionally, both pendulum motion and wave motion involve the transfer of energy.
Why will an unanchored boat in the ocean move up and down in place but not move towards shore?
To be clear, motion to the left and right also exists in the ocean, and the unanchored boat stays in place because there is no net movement in the direction of the shore. Of course, we'll assume that there is no net wind movement in a set direction to discuss your question. The movement of the unanchored boat is produced by the transfer of energy through seawater via wave motion. To understand how waves propagate through seawater, think of the ocean as a flexible bulk material. To understand how the waves propagate through the ocean, think of seawater as a flexible, continuous bulk medium held together in its form by the extensive network of hydrogen bonds between individual water molecules. Consider a wave of air molecules moving toward the surface of the ocean. The energy of the wave transfers through a cascade of collisions between neighboring air molecules and propagates into the ocean. As the wave propagates through the ocean, oscillations and vibrations begin to deform the seawater in a given direction (say, to the left). The force of the leftward moving wave progressively weakens as the energy of the wave disperses outward until it equals the intermolecular forces between water molecules that pull the wave in the opposite direction (to the right). The continuously increasing leftward energy transfer begins to form a rightward restoring force that reverses the seawater deformation to the left. Seawater restoration proceeds until the intermolecular forces of water molecules weakens to the point where rightward wave motion becomes dominant again, completing a full cycle of left to right wave motion. This cycle repeats over and over again for each of the waves propagating in all directions, producing the up-down, left-right periodic oscillations of the unanchored boat. Since the seawater deformation caused by each wave is fully reversed by a restoration force equal in magnitude and opposite in direction, there is no net movement toward the shore and the boat just continues oscillates in place.
