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The force that gets the electrons moving in an organ is an external force. The energy is provided by an electrical current that is generated from an external source such as an electrical outlet or a battery. This energy is then converted into mechanical energy in the form of motion which causes the electrons to move.
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Were does the kinetic energy of moving electrons come from?
The kinetic energy of moving electrons comes from the electromagnetic force exerted on the electrons as they interact with other charged particles in the material they are moving through. This force accelerates the electrons, giving them kinetic energy.
Does an electric field exert a force on a beam of moving electrons?
Yes, an electric field exerts a force on a beam of moving electrons. The force exerted on the electrons by the electric field causes them to accelerate in the direction of the field. This acceleration can be measured and explained using Coulomb's law and the equation for the force on a charged particle in an electric field.
How moving electrons of space is being deflected by an electric field?
When an electric field is applied to moving electrons in space, the field exerts a force on the electrons due to their charge. This force causes the electrons to deviate from their original path and change direction. The amount of deflection depends on the strength of the electric field and the velocity of the electrons.
What exerts the magnetic force?
The magnetic force is exerted by moving electric charges, such as electrons. When these charges move, they create a magnetic field. This magnetic field can interact with other moving charges to produce a force.
What keeps electrons moving around the nucleus?
Electrons move around the nucleus due to the attractive force between the positively charged protons in the nucleus and the negatively charged electrons. This force, called electrostatic attraction, keeps the electrons in orbit around the nucleus.
Were does the kinetic energy of moving electrons come from?
The kinetic energy of moving electrons comes from the electromagnetic force exerted on the electrons as they interact with other charged particles in the material they are moving through. This force accelerates the electrons, giving them kinetic energy.
Does an electric field exert a force on a beam of moving electrons?
Yes, an electric field exerts a force on a beam of moving electrons. The force exerted on the electrons by the electric field causes them to accelerate in the direction of the field. This acceleration can be measured and explained using Coulomb's law and the equation for the force on a charged particle in an electric field.
How moving electrons of space is being deflected by an electric field?
When an electric field is applied to moving electrons in space, the field exerts a force on the electrons due to their charge. This force causes the electrons to deviate from their original path and change direction. The amount of deflection depends on the strength of the electric field and the velocity of the electrons.
What exerts the magnetic force?
The magnetic force is exerted by moving electric charges, such as electrons. When these charges move, they create a magnetic field. This magnetic field can interact with other moving charges to produce a force.
What keeps electrons moving around the nucleus?
Electrons move around the nucleus due to the attractive force between the positively charged protons in the nucleus and the negatively charged electrons. This force, called electrostatic attraction, keeps the electrons in orbit around the nucleus.
What does a unmoving object have to have to start moving?
An unmoving object needs a force to be applied to it in order to start moving. This force can come from an external source like a push or pull, or from internal sources like stored energy or tension.
The force that moving charged particles exert on one another is called?
The force that moving charged particles exert on one another is called the electromagnetic force. This force is responsible for the interaction between charged particles such as electrons and protons.
What is an example of internal force?
A baseball is a great example of an internal force. The particles holding the baseball together is an internal force. But a baseball bat hitting the baseball is not an internal force, because an internal force is a force exerted by one part of a structure on another. The bat hitting the ball is an external force. Another example is a car. The pistons pushing the rods, the axle pushing the wheels, the wheels moving the car...etc. All these things are internal forces working on the car because the these things are all inside the car. But the friction created by the wheels of the car on the ground is an external force, as is the force holding the car up. Hope this helps!
What is the force thea holds an electron to an atom?
The electromagnetic force (protons are positive and electrons are negative, so they attract), which is manifested into Coulomb's force of attraction. The reason that electrons will not fall into the nucleus is due to the electron's energy; it is moving fast enough to not collide with the nucleus.
What causes an electric current to keep moving?
An electric current keeps moving because of the presence of an electric field. The electric field exerts a force on the charged particles (usually electrons) in the conductor, causing them to continue moving. In a closed circuit, the movement of electrons from the negative to the positive terminal of the power source ensures a continuous flow of current.
How is magnetic-force produced?
Magnetic force is produced by moving electric charges. When electrons move through a conductor, they create a magnetic field around the conductor. This is known as electromagnetism and is the basis for the generation of magnetic force.
Can moving electrons through a magnetic field can produce an electric current?
Yes, a moving electron in a magnetic field can induce an electric current. This is the principle behind electromagnetic induction, where a changing magnetic field induces an electric current in a conductor.
