Electric field lines v.s. fieldlines1/8/2024 Such clumping doesn't come from a discrete variation in Saturn's gravitational field, but instead from local interactions of the "test particles." The closest example I can think to this is Saturn's rings: You have a bunch of matter particles orbiting peacefully and somewhat smoothly around a planet, but the local interactions cause clumping, which is evident by the substructure of the rings, for example tiny moons, or moonlets (). It's hard to do such a visualization, as was done for the magnetic and electric fields above, simply because gravity is too weak on a human scale. There would be, however, random clumping of particles together due to the local gravitational attractions. These patterns would NOT bunch together to form "lines" similar to the first two pictures, because there would be no local dipole interactions. However, you could use a lot of elliptically shaped masses, which would then rotate so their long axis pointed along the field lines. If you then somehow suspended a bunch of point particles in the space between them, they would not align with the field lines, because you can't create mass dipoles (again, there are no negative masses). In principle, however, if you put together masses, you would get field lines that looked like this: In the case of gravity, you can't form such a pattern, because there are no "negative charges" for gravity objects only have positive mass. An electric field from two oppositely charged probes polarizes the seeds into little dipoles, which then align with the field: Sure enough, this has been done with grass seeds floating in oil. You can do a similar experiment with electric fields instead, and you would expect the same result, since the "test particles" would form electric dipoles and clump. The clumping is NOT a property of the magnetic field from the large magnet, it is a consequence of the magnetic fields of the small iron filings. This causes the clumping into lines that you see, as the opposite ends of the dipoles move together. In addition, each little dipole feels a small force from the other nearby dipoles, and they move to minimize their local energy. This dipole feels the force of the magnet, and aligns in the direction of the field lines. The reason for the creation of these pretty iron filing shapes is that each little iron filing, when subject to a magnetic field, becomes a little dipole itself. It sure looks like field lines, right? Actually, this clumpiness has nothing to do with field lines it's just a coincidence that it looks like lines (or perhaps it inspired the idea of field lines?). Ironically, when you do the classic magnet and iron filing experiment, this is what you see: Just remember that between any two such field lines, the field strength is just as strong as on the lines themselves. (Even so, they are useful lines to draw, and even contain weakly quantitative behavior, since the field strength is proportional to the density of field lines. The "field lines" taught in many classes and used by physicists to visualize field strengths are purely to guide the eye they don't have physical meaning. Thus, the electric field intensity at the point will have two directions, which is absurd.Great question, and one that can easily lead to confusion, due to an accident of nature.įirst of all, electric, gravitational, AND magentic fields are all completely smooth. If the electric field lines intersect, then two tangents could be drawn at their point of intersection. Why don't electric field lines intersect ? Also, this is the path on which a positive test charge will tend to move if free to do so. The tangent to a line at any point gives the direction of the electric field at the point.If the electric field in a given region of space is zero, electric field lines do not exist.These field lines always flow from higher potential to lower potential.The electric field lines can never form closed loops, as line can never start and end on the same charge.In an uniform electric field, the field lines are straight, parallel and uniformly spaced.The number of electric field lines leaving a positive charge or entering a negative charge is proportional to the magnitude of the charge.Electric field lines always begin on a positive charge and end on a negative charge, so they do not form closed curves. Electric field lines have some important and interesting properties, let us study them.
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