The positive charge is typically placed in a location where it can influence the behavior of nearby charged particles or electric fields. In electrostatics, positive charges are often represented by protons or positive ions, and they can be found in various configurations, such as isolated in space, at the center of an atom, or on the surface of a conductor. The specific placement depends on the context of the problem or system being analyzed.
A positive charge points in the direction of the electric field it creates or is placed in. By convention, electric field lines start from positive charges and point toward negative charges. Therefore, if you have a positive charge, the electric field lines will emanate outward from it. In summary, a positive charge points away from itself in the direction of the electric field.
A positive charge placed next to a negative charge will attract each other due to the difference in their charges. Positive and negative charges attract each other according to the basic principle of electricity.
-- It depends on the value of the positive test-charge, and on the quantity, sign, and physical distribution of the charges situated around that midpoint. -- It also depends on the mass of the object carrying the positive test-charge. Sadly, none of this information is included in the question.
Electric Field between positive and negative charges. If the Electric Field in which both the positive and negative charges are present is stronger than the Electric Field between the two charges we are talking about, the the negative charge will move away from the positive charge in that positive direction of the field. If not, then the negative charge will get attracted to the positive charge and stay at the position of the positive charge. It will be pulled toward the source of the electric field. (Novanet)
A positive charge is a positive electrical charge. Particles with no charge are called neutral particles.
A positive electric field strength indicates that the field is directed away from a positive charge or towards a negative charge. It signifies the direction in which a positive test charge would move if placed in the electric field.
A positive charge will move in the direction of the arrows on the electric field lines. Electric field lines show the direction a positive test charge would move if placed in the field.
A positive charge points in the direction of the electric field it creates or is placed in. By convention, electric field lines start from positive charges and point toward negative charges. Therefore, if you have a positive charge, the electric field lines will emanate outward from it. In summary, a positive charge points away from itself in the direction of the electric field.
A positive charge placed next to a negative charge will attract each other due to the difference in their charges. Positive and negative charges attract each other according to the basic principle of electricity.
The potential of a charge placed at infinity is zero. This is because the potential at a point due to a charge is the work done in bringing the unit positive charge from infinity to that point, and since no work is done to bring a charge from infinity to itself, the potential at infinity is zero.
Electric fields point outward from positive charges and inward toward negative charges. This direction represents the direction of the force that a positive test charge placed in the field would experience.
-- It depends on the value of the positive test-charge, and on the quantity, sign, and physical distribution of the charges situated around that midpoint. -- It also depends on the mass of the object carrying the positive test-charge. Sadly, none of this information is included in the question.
Electric Field between positive and negative charges. If the Electric Field in which both the positive and negative charges are present is stronger than the Electric Field between the two charges we are talking about, the the negative charge will move away from the positive charge in that positive direction of the field. If not, then the negative charge will get attracted to the positive charge and stay at the position of the positive charge. It will be pulled toward the source of the electric field. (Novanet)
To determine the direction of the electric field, you can use a positive test charge. The direction of the electric field is the direction in which a positive test charge would move if placed in that field.
Electric field lines are drawn with arrows to show the direction of the force that a positive test charge would experience if placed in the field. The direction of the electric field at any point is the direction that a positive test charge would move when placed in the field at that point.
It will be directed away from the positive charge. It will attract any other negative charge and repel any positive charge. Its magnitude is given by E= KQ/R where K = 9x 109 C2m-2N-1 Q is the charge producing field R is the point where electric field is to be calculated
Electric field lines point towards the direction that a positive test charge placed in the field would move. They represent the direction and magnitude of the force that a positive charge would experience in that field.