Deck 16: Electric Force and Field

Describe the cell membrane modelled by electrically charged plates.

Consider two electric dipoles in empty space. Each dipole has zero net charge. Does an electric force act between the dipoles even though their net charge is zero? Explain.

Explain what is meant by a "neutral atom," a "positively charged ion," and a "negatively charged ion."

Freezing occurs when hydrogen bonds between water molecules begin to form.

Ions in a salt can be modelled with an electric dipole system.

Cell membranes can be modelled with two charged plates separated at a distance equal to the thickness of the membrane.

The temperature of water must be above a threshold value before any hydrogen bonds are broken.

All atomic particles carry an electric charge, either positive or negative.

When a third charge q₀ is inserted on the line between two charges, Q₁ and Q₂, each having the same sign, the position at which q₀ is in equilibrium between Q₁ and Q₂ does not depend on the sign or magnitude of q₀.

The reason symmetric molecules CH₄ and SiH₄ have very low boiling temperatures is that they have no dipole moment.

Show that a dipole placed in a uniform electric field, with its axis making an angle to the direction of the field, will experience a restoring torque tending to align the dipole with the field.

Rubber rods charged by rubbing with cat fur repel each other. Glass rods charged by rubbing with silk repel each other. A rubber rod and a glass rod charged respectively as above attract each other. A possible explanation is that all rubber rods always have an excess of positive charge on them.

Describe how, experimentally, you could distinguish a gravitational from an electric field.

Discuss the similarities and differences between Newton's law of gravitation and Coulomb's law.

Two charged particles exert an electric force on each other, according to Coulomb's law. What relationship do these forces have to each other? Discuss in terms of Newton's third law.

Figure 16.1 Electric dipole model for the water molecule.
In the water molecule (Fig. 16.1), the electric field at the midpoint, P₂, between the hydrogen atoms is directed away from the oxygen molecule.

If an electron beam enters a region of electric field pointing upward, the beam will be bent downward in a vertical plane.

In an electric field, the dipole axes of polar molecules align with the field so that the positively charged end points in the direction of the field.

The electric field in the vicinity of a collection of charges, all of the same sign, can never vanish.

Hospital personnel must wear special conducting shoes while working around oxygen in an operating room. Why? What would otherwise happen if the shoes were rubber soled?

Material composed of polar molecules is inserted between a pair of parallel plates on which equal and opposite charges reside. What effect does the electric field of the parallel plates have on the polar molecules? Show that this is equivalent to a layer of charge forming on the surfaces of the material, of opposite sign to the charge on the adjacent plate.

Explain why electric field lines can never cross.

Nerve cell membranes have electric fields associated with a charge of the opposite sign on the inside and outside surfaces of the membrane. The walls of the membrane will therefore experience attraction toward each other, resulting in a compression of the membrane. Assuming there are 2 × 10⁴ charges, each of magnitude e (= 1.6 × 10^-19 C), on the membrane, and that the cell has a diameter of d = 2 µm, estimate the force per unit area of this compression.