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yes because they start from the positive charge and ends at the negative charge so closed path
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Do magnetic field lines always cross?
Actually, they NEVER do.
If the electric fields of two charged objects form a closed pattern of field lines how are the objects charged?
They would be "oppositely" charged. In other words, one object would need to be positive and the other would need to be negative.
How are magnetic field lines described?
Magnetic Field Lines Show Magnitude and Direction:When the lines of the magnetic field are close together the magnetic field is strong. In a region where the line density is high, one says that it has great intensity or strength. Technically, the density of lines is proportional to the magnitude of the field.The direction that magnetic field lines are oriented provides the information on the direction of the field, with the convention that the lines have arrows drawn so the lines exit from the North pole of a permanent magnet, or equivalently, the arrows point in the direction that the North end of a compass needle would point if placed on the line.More Information:Magnetic field lines do not really exist any more than electric field lines exist, but both are extremely valuable representations of the strength and direction of magnet (or electric) fields. (Pictures of field lines are human creations to help understand fields, but the pictures of field lines that are correctly drawn do provide a faithful representation of the mathematical description of the field.)When one says a magnetic field is "strong" one does not mean that it exerts a great force on another magnetic object. Strength of a magnetic field is defined in terms of torque, not force. Here is how.Magnetic Vector Field Definition:If a magnetic field exists at a certain point, then one characterizes it with a strength and direction. Indeed, one can do this at all points and know the magnitude and direction of the field at all points. Because vectors have magnitude and direction, we can associate a vector with the magnetic field at any point and that is why one says that a magnetic field is a vector field.Magnetic Field Direction:We define strength or magnitude of the field using the classic behavior that we see when we use a compass. The field exerts a torque on the compass needle to orient it. One end of the compass is marked "North" because, in the absence of any other field, the compass needle points to the "North" geographic pole of the Earth. Using this definition, when a compass is brought near a permanent magnet, the North end of the compass is said to point towards the South end of the magnet. (North poles attract South poles.) This pointing direction can be mapped out in the whole space around the bar magnet, orienting the compass not just flat or horizontal, but in all directions so as to determine which way the magnetic field points for all positions in the space around the permanent magnet. (This works equally well for electromagnets, but we describe it for the most simple situation.)Magnetic Field Strength:The field direction of at each point, as described above, is the direction the North end of the compass needle points when there is zero torque on the needle. If one turns the needle so it is perpendicular to the field direction, then the needle experiences maximum torque. That torque measures the strength or magnitude of the field. Thus, once you set the strength scale by assigning one value of the field strength for one particular compass, you can map out the field strength at all points with the same compass and you get the magnitude and direction of the magnetic field everywhere.Magnetic Field Lines:The above process produces a vector field meaning that at every point in space one could draw an small arrow with a magnitude and direction indicating the field. Such a drawing produces a picture a bunch of arrows in the space around the magnet representing the magnetic field. That is a perfectly good representation of a vector field.One can also create a line representation of a vector field, magnetic, electric or other. For the magnet above, if you start at a point on the North end of the magnet and draw a line in the direction of the arrow, you immediately encounter another arrow. At the point of the new arrow you continue drawing the line in the direction of that arrow, until you get to the next arrow which gives the next direction and on and on. Basically, if you start at the North end of the magnet and draw a line in a direction that follows the directions of the arrows, that line ends up at the south end of the magnet. One can the pick a new starting position on the surface of the magnet and repeat the process. Doing this over and over produces a whole set of lines which eventually fills the entire space around the magnet.The set of lines drawn are not the magnetic field lines. But, each of the lines drawn does follow a magnetic field line. That sounds odd, but to fairly represent the strength of the field, one has to have one more condition applied that determines how many lines are drawn. That condition is that the number of lines in any region of space is proportional to the strength of the field in that region. That requires some additional rule because the number or density of lines won't communicate the field strength if one just draws lines wherever one likes.Density of Magnetic Field Lines:When using field lines to represent a vector field (electric or magnetic or whatever) one needs the information of both magnitude and direction and the individual lines only give direction. So, convention is that the number of lines that you draw in any particular region of space is proportional to the strength (magnitude) of the field in that region. That is hard to do. Fortunately, magnetic field lines have a special property that makes this easier.Magnetic field lines never begin or end.The lines in a picture of a bar magnet makes it look like lines exit the North end and enter the South end and they do, but they keep going through the interior and come out the opposite end forming closed loops. Usually the part of the loops inside the magnet are not drawn, but they exist. It is clearer for electromagnets where the inside is visible in the drawing.Drawing Lines:The technical aspects of drawing the lines is too tricky to explain in detail, but here is a simple and correct approach.First, decide how many lines are to be drawn. More is better, but let us suppose 100 for now. That means that all 100 must come out from the parts of the magnet deemed to be North and into the parts identified as South. That includes the ends and the sides and all regions of the surface where lines may go in or out. Draw more lines in the region where strength of the field at the surface is high and fewer out of regions where the strength is low. You have arranged the lines with the right density when putting your imaginary compass into a region with some density of lines will produce a maximum torque corresponding to the field strength. This all sounds a lot easier than it is.They form complete loops.
What is the angle between lines of force and equipotential lines in an electrical field?
The angle is a right angle.
What instrument measures the electric equipotential?
Multimeter is an instrument that measures electric equipotential. Equipotential lines can be determined by connecting various points of electric potential or voltage.
What are three facts about electric field lines?
1. Electric field lines of force originate from the positive charge and terminate at the negative charge. 2. Electric field lines of force can never intersect each other. 3. Electric field lines of force are not present inside the conductor, it is because electric field inside the conductor is always zero. 4. Electric field lines of force are always perpendicular to the surface of conductor. 5. Curved electric field lines are always non-uniform in nature.
Do electric and magnetic fields always form closed loops?
Magnetic fields do, because there's no such thing as an isolated magnetic "pole", and a magnetic line always starts and ends at opposite poles of the same magnetized object. But electric fields don't. You can easily have a bundle of isolated positive charge over here and a bundle of isolated negative charge over there, whereupon the lines of the electric field start on one bundle and end on the other bundle. But electric field lines can also exist in closed loops, and they do that in radio waves, where the electromagnetic field propagates with an electric field component and a magnetic field component, and they both form closed loops.
Which is true of magnetic field lines but not electric field lines?
they show wich way iron shavings would align themselves They always make closed loops. Electric field lines can either form closed loops or they can start and finish on isolated electric charges. Magnetic field lines always only form closed loops.
Why electric field lines are always perpendicular to the surface of the conductor?
to save the static character of conductor in the presence of electric field
What do lines represent in an electirc field diagram?
The lines in each diagram represent an electric field. The stronger the field, the close together the lines are.
What do lines represent in an electric field diagram?
The lines in each diagram represent an electric field. The stronger the field, the close together the lines are.
Why electric field lines cannot have sudden brakes in between them?
electric field lines represents electric field at that point but if it has break somewhere then it signifies the absence of electric field and it is not possible.....
What do you mean by electric flux in electrostatics?
Under an electric field, magnitude and direction of electric intensity is different in every point.If the electric intensity can be defined through a closed line (direction of electric intensity will be along the tangent of any point of that line)this is called electric lines of force. Electric lines of forces passing through an closed electric surface perpendicularly, is called electric flux.
How are the lines of force drawn around a single charge electric field?
always towards the charge
One of the differences between electric and magnetic fields is that magnetic field lines always form closed loops?
One of the differences between electric and magnetic fields is that magnetic field lines always form closed loops. true
What is electric lines of force?
electric lines of force are imaginary lines defined by the paths traced by unit charges placed in an electric field. Lines of force are everywhere parallel to the electric field strength vector. Their principal use is as a convenient means of picturing the geometry of an electric field.
Are electric field lines real?
No, they only help us understand electric fields.
