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Unformatted text preview: a 'Piiyszm ’ ‘ HOMEWORK SET 3»
Instructor: Professor Bandy “ ’“i 5"» ‘3 Finite Cl} Calculate the electric potential energy of the group of charges in Fig. I . 63 A water molecule perpendicular to an electric ﬁeld has 1.5 x I 0'21 f more potential energy than a water
molecule aligned with the field. its dipole moment is 6.2 x 1’ 0’30 Cm. Calculate . A proton with an initial speed of 750,000 m/s is brought to rest by an electric field. 3. Did the proton
move into a region of higher potential or lower potential? Explain. b. Calculate the potential difference
that stopped the proton. a. in Fig. 2, which of the capacitor plates is positive? Explain. b. Calculate inside the capacitor.
e. Calculate the potential energy of a proton at the midpoint of the capacitor. Calculate the electric potential at a point centered in the charge distribution of Fig. I . A ~40. 0 11C point charge and +20.0 nC point charge are 15 cm apart on the xaxis. 3. Calculate the
electric potential at the point on the x—axis where the electric ﬁeld is zero. 1). Find the magnitude and
direction of the electric ﬁeld at the point on the xaxis Where the electric potential is zero. The annulus shown in Fig. 3 carries a uniform surface charge density 6. 2. Find an expression for the potential at an arbitrary point P on its axis. b. If a —> 0 show that this expression. reduces to the potential
on the axis of a. imiformly charged disk. A dipole with charges of i q and a separation of 2a is located a distance x from a point charge +Q. The dipole moment vector is perpendicular to the x axis. See Fig. 4. 3. Find expressions for the magnitude of
the net torque and net force on the dipole in the limit of x >> a. bi What is the direction of the net force?
What is the ﬁnal position of dipole? The electric potential at points in the xy plane (in m) is given by V = 2.0x“9 — 3.0322 in V. In unitvector notation, ﬁnd the electric ﬁeld E at the point (3.0 m, 2.0 m). 10. Two electrons are fixed 2.0 cm apart. Another electron is shot horn inﬁnity and stops midway between
the two. What is its initial speed?
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This note was uploaded on 01/10/2012 for the course PHYS 2114 taught by Professor Bandy during the Spring '08 term at Oklahoma State.
 Spring '08
 Bandy

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