Honors Chemistry Practice Test PDF

Summary

This practice test covers Light and Quantum Theory in Honors Chemistry. It includes multiple-choice and free-response questions, focusing on fundamental concepts relating energy, frequency, wavelength of light and hydrogen spectral equations.

Full Transcript

Honors Chemistry – Practice Test
Light and Quantum Theory

Some information that you may find useful:

Speed of light (c) = 3.0 × 108 m/s E = hν c = λν

Planck's constant (h) = 6.626 × 10–34 J⋅s Wavelength = λ

Frequency = ν hertz (Hz) = cycles/sec

For the hydrogen atom ΔE = –2.178 × 10–18 J (1/nf2 – 1/ni2)

1 mole = 6.022 × 1023

1 nano meter (nm) = 10–9 m Size of hydrogen atom = 1 × 10-10 m

Multiple Choice:
1. Which of the following statements is (are) TRUE?
1. The product of wavelength and frequency of light is a constant.
2. As the energy increases, the frequency of the radiation decreases.
3. As the wavelength of light increases, the frequency increases.
a) 1 only b) 2 only c) 3 only d) 1 and 3 only e) 2 and 3 only
2. The characteristic light spectrum of an element is produced when
a) the energy level of the nucleus is increased
b) electrons drop back to lower energy levels
c) electrons are raised to higher energy levels
d) electrons are emitted by an atom.

3. The relationship between the energy of an atom and the electron’s distance from the nucleus is
basically
a) the greater the energy the farther the electron is from the nucleus.
b) the greater the energy the closer the electron is to the nucleus.
c) the distance of the electron from the nucleus is unrelated to the atom’s energy.
d) electrons of all energies remain the same distance away from the nucleus.

4. According to the quantum theory of light, the separate packets of energy by which the light waves
travel are called
a) molecules
b) protons
c) ions
d) neutrons
e) photons

5. After an electron drops back from the third to the second energy level, the atom is approaching
the
a) ground state.
b) positively charged state.
c) excited state.
d) negatively charged state.

6. A radio station broadcasts at 105.2 MHz. The wavelength of the signal is _______ m.
a) 3.10
b) 2.85
c) 2.90
d) 3.02
e) 3.84
7. Electromagnetic radiation with a wavelength of 531 nm appears as green light to the human eye.
The energy of one photon of this light is 3.74 × 10–19 J. Thus, a laser that emits 1.3 × 10–2 J of
energy in a pulse of light at this wavelength produces _____________ photons in each pulse.
a) 2.9 × 10–17
b) 9.2 × 10–24
c) 1.8 × 1019
d) 3.5 × 1016
e) 6.5 × 1013

8. The n = 2 to n = 6 transition in the Bohr hydrogen atom corresponds to the _________ of a photon
with a wavelength of _________ nm.
a) emission, 410
b) absorption, 410
c) absorption, 660
d) emission, 94
e) emission, 390

9. When the electron in a hydrogen atom moves from n = 8 to n= 2 light with a wavelength of
__________ nm is emitted.
a) 657
b) 93.8
c) 411
d) 487
e) 389

10. The frequency of electromagnetic radiation required to promote an electron from n = 2 to n = 4 in
a Bohr hydrogen atom is ________ Hz.
a) 4.13 × 10–19
b) 6.17 × 1014
c) 5.46 × 10–19
d) 8.22 × 1014
e) 4.13 × 1019

11. A mole of red photons of wavelength 725 nm has ________ kJ of energy.
a) 2.74 × 10–19
b) 4.56 × 10–46
c) 6.05 × 10–3
d) 165
e) 227
12. Which of the following contains a set up invalid quantum numbers?
a) n = 3; l = 2; ml = -2; ms = -½
b) n = 2; l = 2; ml = -2; ms = -½
c) n = 1; l = 0; ml = 0; ms = -½
d) n = 5; l = 4; ml = -2; ms = +½

Free Response:
1. Rank the following types of electromagnetic radiation (red light, radio, gamma rays) in order of
increasing:
Energy:

Frequency:

Wavelength:

2. Palladium has a first ionization energy of 805 kJ/mol. Is a laser with a wavelength of 552 nm
capable of ionizing a palladium atom?

3. One of the very bright lines of light emitted by the sun has a frequency of 4.62 × 1014 Hz.
What is the wavelength of this light?

4. How long does it take for light to travel from the sun to Jupiter? Jupiter is 778 million kilometers
(7.78 × 108 km) from the sun.

5. Light, in the form of photons, is emitted from atoms when the electron falls from a high energy
level to a lower energy level.
a) What is the energy difference between the n = 5 and the n = 2 principal energy levels in the
hydrogen atom?
 b) What is the wavelength of light associated with this energy difference?

6. Just as an atom loses energy in the form of a photon when an electron falls from a high energy
level to a lower energy level, you can excite an atom by shining a photon of light on the atom.
This would “push” the electron up to higher energy levels from lower energy levels. You can even
remove an electron completely from a neutral atom by shining a photon with sufficient energy onto
a neutral atom. The total energy required to ionize 1 mole of sodium atoms to sodium 1+ ions (i.e.
removing one electron from each atom) is 497 kJ.

a) Calculate the energy that is required to ionize just one atom of sodium to a sodium 1+ ion.

b) Calculate the wavelength of light that would be able to ionize a sodium atom. Can you see this
light? Explain briefly.

7. Identify the n and l quantum numbers for the following subshells. Then state the possible values
for the ml quantum number.
a) 6p

b) 3s

c) 4d

d) 5p