Blackbody radiation shifts and magic wavelengths for atomic clock research
Atomic Structure and Radiation REVIEW GAME
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Atomic Structure and Radiation REVIEW GAME. To complete this review game: You will need a copy of the Periodic Table. You will NOT need a calculator. - PowerPoint PPT Presentation
Transcript of Atomic Structure and Radiation REVIEW GAME
List the following electromagnetic spectrum wave types in order from lowest energy to highest energy:
Gamma raysInfraredMicrowavesRadiowavesUltravioletVisible lightX-rays
List the following electromagnetic spectrum wave types in order from lowest energy to highest energy:
RadiowavesMicrowavesInfraredVisible light UltravioletX-raysGamma rays
What is the relationship between wavelength and frequency in the electromagnetic spectrum?
What is the relationship between wavelength and frequency in the electromagnetic spectrum?
As wavelength decreases, frequency increases
What is the relationship between frequency and energy in the electromagnetic spectrum?
What is the relationship between frequency and energy in the electromagnetic spectrum?
As frequency increases, energy increases
Which of the wave types within the electromagnetic spectrum are potentially ionizing?
Which of the wave types within the electromagnetic spectrum are potentially ionizing?
UltravioletX-raysGamma rays
Which of the statements below is an accurate description of what occurs during ionization of an atom?a. An atom loses a proton and becomes a negatively charged ion.b. An atom loses an electron and becomes a positively charged ion.c. An atom loses an electron and becomes a negatively charged ion. d. An atom gains a neutron and its atomic mass increases by 1.
Which of the statements below is an accurate description of what occurs during ionization of an atom?a. An atom loses a proton and becomes a negatively charged ion.b. An atom loses an electron and becomes a positively charged ion.c. An atom loses an electron and becomes a negatively charged ion. d. An atom gains a neutron and its atomic mass increases by 1.
How many prot0ns, neutrons and electrons in an atom of Platinum?
How many prot0ns, neutrons and electrons in an atom of Platinum?Protons = 78Neutrons = 117Electrons = 78Referring to the Periodic Table, we can see that platinum, Pt, has an atomic number of 78. Thus Pt has 78 protons. As we are speaking of an uncharged atom, we know that the number of electrons is equal to the number of protons, and is therefore also 78. Referring to the Periodic Table, we can see that platinum has an average atomic mass of 195.08 amu. Rounding to the nearest whole number gives 195 amu. As amu = # protons + # neutrons, we can calculate # neutrons = amu - # protons, which is 195 – 78 = 117. Thus platinum has 117 neutrons.
Element identity (what element it is) is determined by A)its atomic number. B)its mass number. C)its neutron number. D)All of these are correct.
Element identity (what element it is) is determined byA)its atomic number. B)its mass number. C)its neutron number. D)All of these are correct.Element identity, meaning the element NAME, is determined solely be the number of protons, and hence solely by atomic number.
How many prot0ns, neutrons and electrons in a Ba2+ ion?
How many prot0ns, neutrons and electrons in a Ba2+ ion?Protons = 56, Neutrons = 81, Electrons = 54Referring to the Periodic Table, we can see that Ba, barium, has an atomic number of 56. Thus Ba2+ has 56 protons. As we are speaking of an ion with a +2 positive charge, this atom has LOST TWO ELECTRONS. Therefore, this ion has 56 - 2 electrons = 54 electrons. Referring to the Periodic Table, we can see that barium has an average atomic mass of 137.327 amu. As electrons do not contribute to the atomic mass (having virtually no mass themselves), this barium ion has the same average atomic mass. Rounding to the nearest whole number gives 137 amu. As amu = # protons + # neutrons, we can calculate # neutrons = amu - # protons, which is 137 – 56 = 81. Thus, our barium ion has 81 neutrons.
Isotopes of an elementa. Are always radioactiveb. Differ in their number of protons
c. Differ in their number of neutronsd. Differ in their number of electrons
Isotopes of an elementa. Are always radioactiveb. Differ in their number of protons
c. Differ in their number of neutronsd. Differ in their number of electrons
Element Q has three common isotopes. If the abundance of 44X is 0.03, the abundance of 45X is 0.25%, and the abundance of 48X is 99.72%, what is the average atomic mass of element Q?
a. 32.89b. 43.63c. 47.99d. 48.76
Element Q has three common isotopes. If the abundance of 44X is 0.03, the abundance of 45X is 0.25%, and the abundance of 48X is 99.72%, what is the average atomic mass of element Q?
a. 32.89b. 43.63c. 47.99d. 48.76
P.S. In this case you don’t even need a calculator to figure it out, since only one of the provided responses is within the atomic mass range of the three isotopes. Clearly the average can’t be LOWER or HIGHER than that range, and therefore responses a., b., and d. CANNOT be correct. Only c. fits within the range of atomic masses of the isotopes.
What atom is depicted in this figure?
What atom is depicted in this figure?
Argon: this atom has 18 protons, meaning anatomic number of 18. referring to the Periodic Table, we can see that the elementwith an atomic number of 18 is Argon.
Which one of the following is a correct representation of an alpha particle?
a. 42He
b. 0-1e
c. 10e
d. 00
Which one of the following is a correct representation of an alpha particle?
a. 42He
b. 0-1e
c. 10e
d. 00
Following α decay, the total number of protons hasa. increased by 2b. decreased by 4c. decreased by 2d. unchanged
Following α decay, the total number of protons hasa. increased by 2b. decreased by 4c. decreased by 2d. unchanged
Following α decay, the atomic number hasa. increased by 2b. decreased by 4c. decreased by 2d. unchanged
Following α decay, the atomic number hasa. increased by 2b. decreased by 4c. decreased by 2d. unchanged
Following α decay, the atomic mass hasa. increased by 2b. decreased by 4c. decreased by 2d. unchanged
Following α decay, the atomic mass hasa. increased by 2b. decreased by 4c. decreased by 2d. unchanged
Alpha decay produces a new atom whose __________ than those of the original atom.a. atomic number is 2 less and atomic mass is 4 lessb. atomic number is 2 less and atomic mass is 2 lessc. atomic number is 2 more and atomic mass is 4 mored. atomic number is 2 more and atomic mass is 2 less
Alpha decay produces a new atom whose __________ than those of the original atom.a. atomic number is 2 less and atomic mass is 4 lessb. atomic number is 2 less and atomic mass is 2 lessc. atomic number is 2 more and atomic mass is 4 mored. atomic number is 2 more and atomic mass is 2 less
Which one of the following is a correct representation of a beta particle?
a. 42He
b. 0-1e
c. 10e
d. 00
Which one of the following is a correct representation of a beta particle?
a. 42He
b. 0-1e
c. 10e
d. 00
Following beta decay, the total number of protons hasa.not changed b.decreased by 1c.increased by 1d.increased by 2
Following beta decay, the total number of protons hasa.not changed b.decreased by 1c.increased by 1d.increased by 2
Following beta decay, the atomic mass hasa.not changed b.decreased by 1c.increased by 1d.increased by 2
Following beta decay, the atomic mass hasa.not changed b.decreased by 1c.increased by 1d.increased by 2
Following beta decay, the atomic number hasa.not changed b.decreased by 1c.increased by 1d.increased by 2
Following beta decay, the atomic number hasa.not changed b.decreased by 1c.increased by 1d.increased by 2
What happens to the atomic mass and atomic number of an atom when it undergoes beta (β) decay?a. The mass number increases by 2 and the atomic number increases by 1.b. The mass number decreases by 4 and the atomic number decreases by 2.c. The mass number does not change and the atomic number increases by 1.d. Neither the mass number nor the atomic number change.a.
What happens to the atomic mass and atomic number of an atom when it undergoes beta (β) decay?a. The mass number increases by 2 and the atomic number increases by 1.b. The mass number decreases by 4 and the atomic number decreases by 2.c. The mass number does not change and the atomic number increases by 1.d. Neither the mass number nor the atomic number change.a.
By what process does uranium-238 decay to thorium-234?
a. alpha decayb. beta decayc. gamma ray emission d. electron capture
By what process does uranium-238 decay to thorium-234?
a. alpha decayb. beta decayc. gamma ray emission d. electron capture
Uranium 238 must have undergone alpha decay to produce thorium-234, since atomic mass has decreased by 4. Furthermore, according to the Periodic Table, uranium has an atomic number of 92, while thorium has an atomic number of 90. Therefore, atomic number has decreased by 2. The complete nuclear decay equation is:
23892U → 234
90Th + 42He
What is the missing product from this nuclear decay reaction: 137
55Cs → 13756Ba + _______________
a. 42He
b. 0+1e
c. 0-1e
d. 00
What is the missing product from this nuclear decay reaction: 137
55Cs → 13756Ba + _______________
a. 42He
b. 0+1e
c. 0-1e
d. 00
Cesium-137 has an atomic number of 55, while Barium-137 has an atomic number of 56. Therefore, during this decay reaction, atomic number has gone up by one while atomic mass is unchanged. Such changes are characteristic of beta decay, thus the missing product is a beta particle. The complete nuclear decay equation is:137
55Cs → 13756Ba + 0
-1e
Thorium undergoes alpha decay. The product of this reaction also undergoes alpha decay. What is the final product of this second decay reaction __________ ?
Thorium undergoes alpha decay. The product of this reaction also undergoes alpha decay. What is the final product of this second decay reaction _radon_ ?The problem tells you that two alpha decay events occur. Since atomic number decreases by two for each alpha decay event, the total decrease in atomic number will be 4. The starting thorium atom has an atomic number of 90. Subtracting 4 gives a final atomic number of 86. Referring to the Periodic Table, we can see that the element radon has an atomic number of 86.
What type of radioactive decay does not change the atomic number or atomic mass of an element?a. electron captureb. gamma ray emissionc. alpha decayd. beta decay
What type of radioactive decay does not change the atomic number or atomic mass of an element?
a. electron captureb. gamma ray emissionc. alpha decayd. beta decay
Gamma rays have no charge and no mass, being a wave rather than a particle, therefore the emission of gamma rays during decay affects neither atomic mass nor atomic number.
A 39Cl atom ejects a beta particle. What is the product of this reaction?
a. 39Ar
b. 39Cl
c. 39S
d. 38Ar
A 39Cl atom ejects a beta particle. What is the product of this reaction?
a. 39Ar
b. 39Cl
c. 39S
d. 38Ar Referring to the Periodic Table we can see that the atomic number of Cl is 17. We know that beta decay causes atomic number to increase by 1, therefore the final atomic mass is 18. Referring to the Periodic Table we see that argon (Ar) has an atomic mass of 18. We also know that beta emission causes no change in the atomic mass, therefore the specific isotope generated is argon-39 . The overall nuclear decay equestion is:
3917Cl o
-1e + 3918Ar
A 200 g sample of lawrencium is left in a container from 8:00 AM one morning until 2:00 PM the next afternoon. If the mass of the sample of lawrencium was 25 g, what is the half-life of lawrencium??a.10 hoursb.1 dayc.5 hours d.30 hours
A 200 g sample of lawrencium is left in a container from 8:00 AM one morning until 2:00 PM the next afternoon. If the mass of the sample of lawrencium was 25 g, what is the half-life of lawrencium??a.10 hoursb.1 dayc.5 hours d.30 hoursSince we started with 200g, after the first half life, 100 g would remain, after the second half life 50 g would remain, and after the third half life 25 g would remain. Thus, the sample in this question has gone through 3 half lives. The total amount of time elapsed from 8:00 am day 1 through 2:00 PM day 1 is a total of 16 + 14 hours. Thus a total of 30 hours have passed. 30 hours divided by 3 half lives, gives a half-life time of 10 hours.
According to this graph, what is that half-life of radioactive material X?a.5,000 yearsb.10,000 yearsc.15,000 yearsd.20,000 years
Time (X 1000 years)
According to this graph, what is that half-life of radioactive material X?a.5,000 yearsb.10,000 yearsc.15,000 yearsd.20,000 years The graph shows that 50 % of materialis left after 5 X 1000
years, which is equal to 5000 years.
Time (X 1000 years)
Complete the following table to describe the decay of carbon-14.
Half-life#
Time in years
Fraction of carbon-14 remaining in sample
Mass of carbon-14 remaining in sample
0 0 1 100 g
5,700 50 g
2 ¼ 17,100
6.25 g
6
Complete the following table to describe the decay of carbon-14.
Half-life#
Time in years
Fraction of carbon-14 remaining in sample
Mass of carbon-14 remaining in sample
0 0 1 100 g
1 5,700 ½ 50 g
2 11,400 ¼ 25 g
3 17,100 1/8 12.5 g
4 22,800 1/16 6.25 g
5 28,500 1/32 3.125 g
6 34,200 1/64 1.562
Consider the following table describing the decay of carbon-14.
Given that carbon-14 undergoes beta decay to form nitrogen-14, how much nitrogen-14 will be present in a sample of carbon-14 after 5,700 years, if that sample originally contained 40 g of carbon-14?
Half-life#
Time in years
Fraction of carbon-14 remaining in sample
Mass of carbon-14 remaining in sample
0 0 1 100 g
1 5,700 ½ 50 g
2 11,400 ¼ 25 g
3 17,100 1/8 12.5 g
4 22,800 1/16 6.25 g
5 28,500 1/32 3.125 g
6 34,200 1/64 1.562
Consider the following table describing the decay of carbon-14.
Given that carbon-14 undergoes beta decay to form nitrogen-14, how much nitrogen-14 will be present in a sample of carbon-14 after 5,700 years, if that sample originally contained 40 g of carbon-14? 20 g of nitrogen-14 will be present in the sample after 5,700 years. We know that half of the carbon-14 sample will have decayed into nitrogen-14 by 5,700 years. We also know that during beta decay, atomic mass does not change. Therefore the mass of nitrogen produced will be equal to the mass of carbon-14 that has been lost. Since ½ of 40 g of carbon-14 = 20 g of carbon-14 decayed by year 5,700, the same mass of nitrogen-14 will have been generated by beta decay = 20 g of nitrogen-14 .
Half-life#
Time in years
Fraction of carbon-14 remaining in sample
Mass of carbon-14 remaining in sample
0 0 1 100 g
1 5,700 ½ 50 g
2 11,400 ¼ 25 g
3 17,100 1/8 12.5 g
4 22,800 1/16 6.25 g
5 28,500 1/32 3.125 g
6 34,200 1/64 1.562
