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www.GOALias.blogspot.comat that point. The charge Q, which is producing the electric field, iscalled a source charge and the charge q, which tests the effect of asource charge, is called a test charge. Note that the source charge Qmust remain at its original location. However, if a charge q is broughtat any point around Q, Q itself is bound to experience an electricalforce due to q and will tend to move. A way out of this difficulty is tomake q negligibly small. The force F is then negligibly small but theratio F/q is finite and defines the electric field:⎛F⎞E = lim(1.9)q →0⎜⎝q⎟⎠A practical way to get around the problem (of keeping Q undisturbedin the presence of q) is to hold Q to its location by unspecified forces!This may look strange but actually this is what happens in practice.When we are considering the electric force on a test charge q due to acharged planar sheet (Section 1.15), the charges on the sheet are held totheir locations by the forces due to the unspecified charged constituentsinside the sheet.(ii) Note that the electric field E due to Q, though defined operationallyin terms of some test charge q, is independent of q. This is becauseF is proportional to q, so the ratio F/q does not depend on q. Theforce F on the charge q due to the charge Q depends on the particularlocation of charge q which may take any value in the space aroundthe charge Q. Thus, the electric field E due to Q is also dependent onthe space coordinate r. For different positions of the charge q all overthe space, we get different values of electric field E. The field exists atevery point in three-dimensional space.(iii) For a positive charge, the electric field will be directed radiallyoutwards from the charge. On the other hand, if the source charge isnegative, the electric field vector, at each point, points radially inwards.(iv) Since the magnitude of the force F on charge q due to charge Qdepends only on the distance r of the charge q from charge Q,the magnitude of the electric field E will also depend only on thedistance r. Thus at equal distances from the charge Q, the magnitudeof its electric field E is same. The magnitude of electric field E due toa point charge is thus same on a sphere with the point charge at itscentre; in other words, it has a spherical symmetry.Electric Chargesand Fields1.8.1 Electric field due to a system of chargesConsider a system of charges q 1, q 2, ..., q nwith position vectors r 1,r 2, ..., r nrelative to some origin O. Like the electric field at a point inspace due to a single charge, electric field at a point in space due to thesystem of charges is defined to be the force experienced by a unittest charge placed at that point, without disturbing the originalpositions of charges q 1, q 2, ..., q n. We can use Coulomb’s law and thesuperposition principle to determine this field at a point P denoted byposition vector r.19