Solution Manual For
Solution manual to Quantum Physics 3rd Edition by Stephen Gasiorowicz
Chapter 1-19business exams, often requiring students to demonstrate knowledge of legal statutes, case law, and their ability to apply legal reasoning. Common types of law
exams include:Essay
CHAPTER 1
1. The energy contained in a volume dV is
U(,T )dV U (,T )r 2dr sindd
when the geometry is that shown in the figure. The energy from this source that emerges
through a hole of area dA is
dAcos
dE(,T ) U (,T )dV
4r 2
The total energy emitted is
/2 dA
dE(,T ) dr d dU (,T ) sin cos
c t 2
0 0 0 4
dA /2
2ctU(,T ) d sin cos
. 4 0
1
ctdAU (,T )
4
By definition of the emissivity, this is equal to EtdA . Hence
c
E(,T ) U (,T )
4
2. We have
c c 8hc 1
w(,T ) U (,T ) | d / d |
U( ) 2
5 ehc/kT 1
This density will be maximal when dw(,T ) / d 0. What we need is
, d 1 1 1 1 eA / A 1
(5 ( )) 0
d 5 eA / 1 6 5 eA/ 1 2 eA / 1
Where A hc / kT . The above implies that with x A / , we must have
5 x 5exbusiness exams, often requiring students to demonstrate knowledge of legal statutes, case
law, and their ability to apply legal reasoning. Common types of law exams include:Essay
A solution of this is x = 4.965 so that
3. The relationship is
h K W
where K is the electron kinetic energy and W is the work function. Here
hc (6.626 1034 J .s)(3 108 m / s) 19
h 5.68 10 J 3.55eV
350 109 m
With K = 1.60 eV, we get W = 1.95 eV
4. We use
hc hc
K K
1 2
1 2
since W cancels. From ;this we get
1 12
h (K K )
2
c 2 1 1
9 9
(200 10 m)(258 10 m) (2.3 0.9)eV (1.60 10 19 )J / eV
(3 108 m / s)(58 109 m)
, 6.64 1034 J .s
business exams, often requiring students to demonstrate knowledge of legal statutes, case law, and their ability to apply legal reasoning. Common types of law exams include:Essay
, 5. The maximum energy loss for the photon occurs in a head-on collision, with the
photon scattered backwards. Let the incident photon energy be h , and the backward-
scattered photon energy be h' . Let the energy of the recoiling proton be E. Then its
recoil momentum is obtained from E p2c 2 m 2c 4 . The energy conservation
equation readsbusiness exams, often requiring students to demonstrate knowledge of legal statutes, case law, and their ability to apply legal reasoning.
Common types of law exams include:Essay
h mc2 h' E
and the momentum conservation equation reads
h h'
p
c c
6. Let h be the incident photon energy, h' the final photon energy and p the outgoing
electron momentum. Energy conservation reads
h mc2 h' p2c2 m2c4
We write the equation for momentum conservation, assuming that the initial photon
moves in the x –direction and the final photon in the y-direction. When multiplied by c it
read
Solution manual to Quantum Physics 3rd Edition by Stephen Gasiorowicz
Chapter 1-19business exams, often requiring students to demonstrate knowledge of legal statutes, case law, and their ability to apply legal reasoning. Common types of law
exams include:Essay
CHAPTER 1
1. The energy contained in a volume dV is
U(,T )dV U (,T )r 2dr sindd
when the geometry is that shown in the figure. The energy from this source that emerges
through a hole of area dA is
dAcos
dE(,T ) U (,T )dV
4r 2
The total energy emitted is
/2 dA
dE(,T ) dr d dU (,T ) sin cos
c t 2
0 0 0 4
dA /2
2ctU(,T ) d sin cos
. 4 0
1
ctdAU (,T )
4
By definition of the emissivity, this is equal to EtdA . Hence
c
E(,T ) U (,T )
4
2. We have
c c 8hc 1
w(,T ) U (,T ) | d / d |
U( ) 2
5 ehc/kT 1
This density will be maximal when dw(,T ) / d 0. What we need is
, d 1 1 1 1 eA / A 1
(5 ( )) 0
d 5 eA / 1 6 5 eA/ 1 2 eA / 1
Where A hc / kT . The above implies that with x A / , we must have
5 x 5exbusiness exams, often requiring students to demonstrate knowledge of legal statutes, case
law, and their ability to apply legal reasoning. Common types of law exams include:Essay
A solution of this is x = 4.965 so that
3. The relationship is
h K W
where K is the electron kinetic energy and W is the work function. Here
hc (6.626 1034 J .s)(3 108 m / s) 19
h 5.68 10 J 3.55eV
350 109 m
With K = 1.60 eV, we get W = 1.95 eV
4. We use
hc hc
K K
1 2
1 2
since W cancels. From ;this we get
1 12
h (K K )
2
c 2 1 1
9 9
(200 10 m)(258 10 m) (2.3 0.9)eV (1.60 10 19 )J / eV
(3 108 m / s)(58 109 m)
, 6.64 1034 J .s
business exams, often requiring students to demonstrate knowledge of legal statutes, case law, and their ability to apply legal reasoning. Common types of law exams include:Essay
, 5. The maximum energy loss for the photon occurs in a head-on collision, with the
photon scattered backwards. Let the incident photon energy be h , and the backward-
scattered photon energy be h' . Let the energy of the recoiling proton be E. Then its
recoil momentum is obtained from E p2c 2 m 2c 4 . The energy conservation
equation readsbusiness exams, often requiring students to demonstrate knowledge of legal statutes, case law, and their ability to apply legal reasoning.
Common types of law exams include:Essay
h mc2 h' E
and the momentum conservation equation reads
h h'
p
c c
6. Let h be the incident photon energy, h' the final photon energy and p the outgoing
electron momentum. Energy conservation reads
h mc2 h' p2c2 m2c4
We write the equation for momentum conservation, assuming that the initial photon
moves in the x –direction and the final photon in the y-direction. When multiplied by c it
read
