Begin2.DVI

9-27. In thermodynamics the internal energy U of a gas is a function of pressure

P and volume V denoted by U =U(P, V ).If a gas is involved in a process where

the pressure and volume change with time, then this process can be described by

a curve called a P-V diagram of the process. Let Q=Q(t) denote the amount of

heat obtained by the gas during the process. From the first law of thermodynamics

which states that dQ =dU +P dV , show that dQ =∂U

∂P

dP +

[

∂U

∂V

+P

]

dV and determine

whether the line integral

∫t 1

t 0

dQ , which represents the heat received during a time

interval ∆t, is independent of the path of integration or dependent upon the path of

integration.

9-28.

(a) If xand yare independent variables and you are given an equation of the form

F(x) = G(y)for all values of xand ywhat can you conclude if (i) xvaries and y

is constant and (ii) yvaries but xis constant.

(b) Assume a solution to Laplace’s equation ∇^2 φ =

∂^2 φ

∂x^2 +

∂^2 φ

∂y^2 = 0 in Cartesian

coordinates of the form φ=X(x)Y(y),where the variables are separated. If the

variables xand yare independent show that there results two linear differential

equations

1

X

d^2 X

dx^2

=−λ and^1

Y

d^2 Y

dy^2

=λ,

where λis termed a separation constant.

9-29. Evaluate the line integral I=

∫

C

F
·d
r, where F
=yz ˆe 1 +xz ˆe 2 +xy eˆ 3 and

Cis the curve
r =
r (t) = cos tˆe 1 + (

t

π+ sin t)ˆe^2 +

3 t

πˆe^3 between the points (1 ,^0 ,0) and

(− 1 , 1 ,3).

9-30. A particle moves along the x-axis subject to a restoring force −Kx. Find

the potential energy and law of conservation of energy for this type of motion.

9-31. Evaluate the line integral

I=

∫

K

(2 x+y)dx +x dy, where Kconsists of straight line segments

OA +AB +BC connecting the points O(0 ,0), A (3 ,3), B (5 ,−1) and C(7,5).