3. Given that the work function of chromium is 4.40 ev, calculate the kinetic energy of electrons emitted from a chromium surface that is irradiated with ultraviolet radiation of wavelength 200 nm. (McQuarrie 1-19)
3. Given that the work function of chromium is 4.40 ev, calculate the kinetic energy of electrons emitted from a chromium surface that is irradiated with ultraviolet radiation of wavelength 200 nm. (McQuarrie 1-19)
Chemistry: The Molecular Science
5th Edition
ISBN:9781285199047
Author:John W. Moore, Conrad L. Stanitski
Publisher:John W. Moore, Conrad L. Stanitski
Chapter5: Electron Configurations And The Periodic Table
Section: Chapter Questions
Problem 5.ACP
Related questions
Question
Pls answer number 3 thank you
![1. Before Planck's theoretical work on blackbody radiation, Wien showed empirically that
AmaxT = 2.90 x10³ m-K
where Amax is the wavelength at which the blackbody spectrum has its maximum value at
a temperature T. This expression is called the Wien displacement law; derive it from the
theoretical expression for the blackbody distribution. (McQuarrie 1-5)
2. Calculate the number of photons in a 2.00 mJ light pulse at (a) 1.06 µm, (b) 537 nm, and
(c) 266 nm. (McQuarrie 1-13)
3. Given that the work function of chromium is 4.40 eV, calculate the kinetic energy of
electrons emitted from a chromium surface that is irradiated with ultraviolet radiation of
wavelength 200 nm. (McQuarrie 1-19)
4. A ground-state hydrogen atom absorbs a photon of light that has a wavelength of 97.2
nm. It then gives off a photon that has a wavelength of 486 nm. What is the final state of
the hydrogen atom? (McQuarrie 1-26)
5. Calculate the de Broglie wavelength for (a) an electron with a kinetic energy of 100 eV,
(b) a proton with a kinetic energy of 100 eV, and (c) an electron in the first Bohr orbit of a
hydrogen atom. (McQuarrie 1-38)
6. If we locate an electron to within 20 pm, then what is the uncertainty in its speed?
(McQuarrie 1-46)*
7. What is the uncertainty of the momentum of an electron if we know its position is
somewhere in a 10 pm interval? How does the value compare to momentum of an electron
in the first Bohr orbit? (McQuarrie 1-47)*
8. Solve the following differential equations:
Y- 4y = 0
y(0) = 2
(at x = 0) = 4
а.
dx2
d²y
b.
dx2
+ 6y = 0
y(0) = – 1
(at x = 0) = 0
- 2y = 0
У(0) %3D 2
(McQuarrie 2-2)
C.
dx
9. Solve the following differential equations:
+ w?x(t) = 0
x(0) = 0
(at t = 0) = vo
a.
dt?
d?x
b.
+ w°x(t) = 0
x(0) = A
(at t = 0) = vo
Prove in both cases that x(t) oscillates with frequency w/2n. (McQuarrie 2-4)
10. Prove that the number of nodes for a vibrating string clamped at both ends is n - 1 for the
nth harmonic. (McQuarrie 2-11)](/v2/_next/image?url=https%3A%2F%2Fcontent.bartleby.com%2Fqna-images%2Fquestion%2F671df763-cbe4-4075-8099-955c174e0ac2%2F3e814d74-f35e-48a5-b65f-1484ee56c7a7%2Fe86g6xh_processed.jpeg&w=3840&q=75)
Transcribed Image Text:1. Before Planck's theoretical work on blackbody radiation, Wien showed empirically that
AmaxT = 2.90 x10³ m-K
where Amax is the wavelength at which the blackbody spectrum has its maximum value at
a temperature T. This expression is called the Wien displacement law; derive it from the
theoretical expression for the blackbody distribution. (McQuarrie 1-5)
2. Calculate the number of photons in a 2.00 mJ light pulse at (a) 1.06 µm, (b) 537 nm, and
(c) 266 nm. (McQuarrie 1-13)
3. Given that the work function of chromium is 4.40 eV, calculate the kinetic energy of
electrons emitted from a chromium surface that is irradiated with ultraviolet radiation of
wavelength 200 nm. (McQuarrie 1-19)
4. A ground-state hydrogen atom absorbs a photon of light that has a wavelength of 97.2
nm. It then gives off a photon that has a wavelength of 486 nm. What is the final state of
the hydrogen atom? (McQuarrie 1-26)
5. Calculate the de Broglie wavelength for (a) an electron with a kinetic energy of 100 eV,
(b) a proton with a kinetic energy of 100 eV, and (c) an electron in the first Bohr orbit of a
hydrogen atom. (McQuarrie 1-38)
6. If we locate an electron to within 20 pm, then what is the uncertainty in its speed?
(McQuarrie 1-46)*
7. What is the uncertainty of the momentum of an electron if we know its position is
somewhere in a 10 pm interval? How does the value compare to momentum of an electron
in the first Bohr orbit? (McQuarrie 1-47)*
8. Solve the following differential equations:
Y- 4y = 0
y(0) = 2
(at x = 0) = 4
а.
dx2
d²y
b.
dx2
+ 6y = 0
y(0) = – 1
(at x = 0) = 0
- 2y = 0
У(0) %3D 2
(McQuarrie 2-2)
C.
dx
9. Solve the following differential equations:
+ w?x(t) = 0
x(0) = 0
(at t = 0) = vo
a.
dt?
d?x
b.
+ w°x(t) = 0
x(0) = A
(at t = 0) = vo
Prove in both cases that x(t) oscillates with frequency w/2n. (McQuarrie 2-4)
10. Prove that the number of nodes for a vibrating string clamped at both ends is n - 1 for the
nth harmonic. (McQuarrie 2-11)
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