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How does the electric potential energy between two positively charged particles change if the distance between them is reduced by a factor of 3?
The electric potential energy between two positively charged particles increases by a factor of 9 if the distance between them is reduced by a factor of 3. This relationship is based on the inverse square law, where potential energy is inversely proportional to the square of the distance between charged particles.
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How would you change the distance between two positively charged particles to increase the electric potential energy by a factor of 4?
To increase the electric potential energy of two positively charged particles by a factor of 4, you would need to decrease the distance between the particles by a factor of 2 (since potential energy is inversely proportional to distance). This is because potential energy between charged particles is given by the equation PE = k(q1*q2)/r, where r is the distance between the particles.
How does the electric potential energy between two positive charged particles change if the distance between them is reduced by a factor of 3?
The electric potential energy between two positive charged particles will increase by a factor of 9 (3 squared) if the distance between them is reduced by a factor of 3. This is because the potential energy is inversely proportional to the distance between the charges squared.
Between which particles would an electric force of attration occur?
An electric force of attraction would occur between positively and negatively charged particles. Positively charged particles are attracted to negatively charged particles, according to the principle of opposites attract in electric forces.
When a positively charged object moves in the same direction as the electric field the electric potential energy of the object is it increases or does it decreases?
If a positively charged object moves in the same direction as the electric field, its electric potential energy decreases. This is because work is done by the electric field on the object as it moves, resulting in a reduction in its potential energy.
At which point will an electron experience a higher electric potential?
An electron will experience a higher electric potential when it moves closer to a positively charged object.
How would you change the distance between two positively charged particles to increase the electric potential energy by a factor of 4?
To increase the electric potential energy of two positively charged particles by a factor of 4, you would need to decrease the distance between the particles by a factor of 2 (since potential energy is inversely proportional to distance). This is because potential energy between charged particles is given by the equation PE = k(q1*q2)/r, where r is the distance between the particles.
What are positively charged electric particles in an atom?
Protons are the only positively charged particles in an atom.
How does the electric potential energy between two positive charged particles change if the distance between them is reduced by a factor of 3?
The electric potential energy between two positive charged particles will increase by a factor of 9 (3 squared) if the distance between them is reduced by a factor of 3. This is because the potential energy is inversely proportional to the distance between the charges squared.
Between which particles would an electric force of attration occur?
An electric force of attraction would occur between positively and negatively charged particles. Positively charged particles are attracted to negatively charged particles, according to the principle of opposites attract in electric forces.
What is the force of repulsion between two positively charged particles?
electric force
What is the force of repulsive between two positively-charged particles?
electric force
When a positively charged object moves in the same direction as the electric field the electric potential energy of the object is it increases or does it decreases?
If a positively charged object moves in the same direction as the electric field, its electric potential energy decreases. This is because work is done by the electric field on the object as it moves, resulting in a reduction in its potential energy.
At which point will an electron experience a higher electric potential?
An electron will experience a higher electric potential when it moves closer to a positively charged object.
At which point will an electron have more electric potential energy?
An electron will have more electric potential energy when it is farther away from a positively charged object.
How does the relationship between work and electric potential energy affect the behavior of charged particles in an electric field?
The relationship between work and electric potential energy influences the movement of charged particles in an electric field. When work is done on a charged particle, its electric potential energy changes, affecting its behavior in the electric field. Charged particles will move in a direction that minimizes their electric potential energy, following the path of least resistance. This relationship helps determine the trajectory and speed of charged particles in an electric field.
What is the relationship between the movement of charged particles and the change in their electric potential or kinetic energy?
The movement of charged particles can lead to changes in their electric potential or kinetic energy. When charged particles move in an electric field, they can experience changes in their electric potential energy. Additionally, the movement of charged particles can also result in changes in their kinetic energy, which is the energy associated with their motion.
What is the force of repulsion between two positively-charged particles?
The force of repulsion between two positively charged particles is directly proportional to the product of their charges and inversely proportional to the square of the distance between them. The force follows Coulomb's law, which states that like charges repel each other.
