For an insulating object, charge does not flow freely and so the voltage at each point on the surface is typically different from its neighbor. For intermediate materials, the time taken to achieve near equipotential surface is several times the time constant.
For objects that have high resistivity and a long time constant, charge will redistribute to equipotential if we wait long enough (and if the field source is not changing rapidly) – but in the meantime surface voltages can be different.
2.4.2 Electrostatic Field in Practical Situations
For a small point or spherical charge with the balancing charge a long way distant, the strength of the electric field falls off rapidly with distance r, as it is proportional to 1/r2. The field line spread out radially (Figure 2.4). In many practical situations the object presenting an electrostatic field source is too large to be considered a point source.
Figure 2.4 Field lines (shown dashed) emerging from a small point or spherical charge.
Figure 2.5 Electrostatic field between parallel plates.
For larger and different shaped objects, the field line pattern can be very different and the fall‐off in field strength can be much less rapid. In practice, the field lines start and finish on conductors at different voltages in the region, and field lines may be more or less curved at any region in space between them.
The electrostatic field between two large flat parallel plates, well away from the plate edges, is uniform (Figure 2.5), and the field lines are parallel between the electrodes. Away from the plate edges, the field E is uniform and is easily calculated from the voltage difference between the plates V and the distance between them d.
If a conductor is placed in an electrostatic field, it has the effect of drawing the field to itself with field lines always emerging at right angles to the conductor surface. In response, charges on the conductor are redistributed until the voltage is the same all over the conductor surface. One of the consequences of this is that any instrument we use to measure an electrostatic field inevitably changes the field it is measuring. Figure 2.6 shows how this happens with the electrostatic field between a metal plate at voltage V and a grounded electrostatic field meter. The field meter actually sees a field higher than the V/d value. The same effect happens of course for any component, PCB or any other electrostatic discharge–sensitive (ESDS) device brought into the field. The density of the field lines at the surface are related to the field strength and surface charge density induced at the surface. A high concentration of field lines indicates a high field strength.
Figure 2.6 Electrostatic field between a field meter and metal plate at voltage V.
Field lines tend to congregate at the tip or edge of an object, and the electrostatic field strength becomes more intense in these regions. Discharges tend to occur preferentially from high field strength regions at sharp edges on objects. This is used to an advantage, for example, in using sharp pins to produce intense fields and corona discharges as a source of ions in an ionizer for charge neutralization.
For a charged insulating surface, the situation is even more complicated. A charged insulator will normally have a highly variable charge density over its surface. The surface voltage is highly dependent on the surface charge density and presence of other materials nearby.
2.4.3 Faraday Cage
For a conducting object in an electric field, charge flows until all points on the surface are at the same voltage. This must be so, as any voltage difference would cause a current to flow in the conductor. If the object is hollow, then the field inside the object is zero, because an equipotential conductor surrounds it (Figure 2.7). An object placed within the hollow conductor would therefore be shielded from the effects of an external field. This hollow conductor is called a Faraday cage.
2.4.4 Induction: An Isolated Conductive Object Attains a Voltage When in an Electric Field
If we consider the behavior of a conductive object as a capacitor, we can quickly understand that the voltage on an isolated conductive object will change under the influence of a nearby charged object and its electric field.
In Figure 2.8 an earthed electrostatic field meter is monitoring the voltage Vm of a metal plate. There is an effective capacitance Cm between the metal object and the field meter. The metal object has no net charge and is initially at zero volts.
Figure 2.7 Faraday cage.
Figure 2.8 Voltage developed on a metal plate in an electric field.
A positively charged object is then brought near. As it approaches, it couples to an increasing amount of negative charge Q on the metal object attracted to the side nearest the positively charged object. The same amount of positive charge is repelled and appears on the side of the metal object nearest the field meter, coupled to an equivalent negative charge on the (grounded) field meter. The field meter sees a positive voltage on the metal object, as voltage on the metal object increases (the capacitor Cm is charged) by an amount.
While the total amount of charge on the plate does not change, an amount –Q is attracted toward the positively charged object to charge Cg, and an amount + Q is repelled to charge Cm.
Note that the metal plate would have a capacitance and voltage with respect to ground, even if the field meter were not present. Although there is now a voltage on the plate, the net charge remains zero (+Q −Q), and it is not charged!
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