"Equipotentials" Example Sentences
1. The electric field lines intersect the equipotentials at right angles.
2. The equipotentials around a point charge are concentric circles.
3. The equipotentials on a positive charge are higher the further away from the charge you go.
4. The equipotentials on a conductor are always perpendicular to the surface of the conductor.
5. The equipotentials on a wire with current flowing through it are parallel to the wire.
6. The equipotentials on a capacitor are perpendicular to the plates.
7. The equipotentials on a sphere with uniform charge are also spheres.
8. The equipotentials on an isolated conductor are all at the same potential.
9. The equipotentials in a region with two point charges are distorted ellipsoids.
10. The equipotentials of a uniform electric field are parallel planes.
11. The equipotentials of a dipole are hyperbolas.
12. The equipotentials of a line charge are cylinders.
13. The equipotentials of a plane with uniform charge are parallel planes.
14. The equipotentials of a charged disk are concentric circles.
15. The equipotentials of a charged cylinder are coaxial cylinders.
16. The equipotentials of a charged square are concentric squares.
17. The equipotentials of a charged sphere are concentric spheres.
18. The equipotentials of a charged torus are coaxial tori.
19. The equipotentials of a charged ring are also rings.
20. The equipotentials of an electric dipole are perpendicular bisectors of the dipole axis.
21. The equipotentials of an infinite line charge are parallel planes.
22. The equipotentials of two point charges of opposite sign are symmetric about the line connecting the charges.
23. The equipotentials of two point charges of the same sign are not symmetric about the line connecting the charges.
24. The equipotentials of a triangular distribution of charge are curved lines.
25. The equipotentials on the surface of a conductor are constant.
26. Equipotentials are useful for visualizing electric fields.
27. Equipotentials provide a way of calculating potential differences.
28. The equipotentials of an electric field due to a point charge form radial lines.
29. The equipotentials of an electric field due to a dipole form closed loops.
30. The equipotentials of an electric field due to a charged plane are parallel planes.
Common Phases
1.
Equipotentials are imaginary lines that represent points of equal potential energy;
2. These lines are perpendicular to electric field lines;
3. Equipotential surfaces are always perpendicular to electric field lines;
4. Conductors have equipotential surfaces since the electric field inside a conductor is zero;
5. Equipotential lines can be used to calculate the electric potential difference between two points;
6. The electric potential difference between two points is equal to the work done by an external force moving a charge along an equipotential surface from one point to another.