Textbook Question
Each of the following transmutations produces a radionuclide used in positron emission tomography (PET).
(a) In equations (i) and (ii), identify the species signified as 'X.'
(i) 14N(p,α)X
(ii) 18O(p,X)18F
(iii) 14N(d,n)15O
Ch.21 - Nuclear Chemistry
Brown14th EditionChemistry: The Central ScienceISBN: 9780134414232
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Table of contents
- Ch.1 - Introduction: Matter, Energy, and Measurement177
- Ch.2 - Atoms, Molecules, and Ions231
- Ch.3 - Chemical Reactions and Reaction Stoichiometry216
- Ch.4 - Reactions in Aqueous Solution189
- Ch.5 - Thermochemistry175
- Ch.6 - Electronic Structure of Atoms168
- Ch.7 - Periodic Properties of the Elements150
- Ch.8 - Basic Concepts of Chemical Bonding177
- Ch.9 - Molecular Geometry and Bonding Theories200
- Ch.10 - Gases179
- Ch.11 - Liquids and Intermolecular Forces113
- Ch.12 - Solids and Modern Materials154
- Ch.13 - Properties of Solutions157
- Ch.14 - Chemical Kinetics199
- Ch.15 - Chemical Equilibrium128
- Ch.16 - Acid-Base Equilibria164
- Ch.17 - Additional Aspects of Aqueous Equilibria163
- Ch.18 - Chemistry of the Environment105
- Ch.19 - Chemical Thermodynamics164
- Ch.20 - Electrochemistry171
- Ch.21 - Nuclear Chemistry122
- Ch.22 - Chemistry of the Nonmetals82
- Ch.23 - Transition Metals and Coordination Chemistry79
- Ch.24 - The Chemistry of Life: Organic and Biological Chemistry16
Brown14th EditionChemistry: The Central ScienceISBN: 9780134414232Not the one you use?Change textbook
Chapter 21, Problem 77b
In 2010, a team of scientists from Russia and the United States reported creation of the first atom of element 117, which is named tennessine, and whose symbol is Ts. The synthesis involved the collision of a target of 24997Bk with accelerated ions of an isotope which we will denote Q. The product atom, which we will call Z, immediately releases neutrons and forms 294117Ts: 24997Bk + Q → Z → 294117Ts + 3 10n (b) Isotope Q is unusual in that it is very long-lived (its half-life is on the order of 1019 yr) in spite of having an unfavorable neutron-to-proton ratio (Figure 21.1). Can you propose a reason for its unusual stability?
Verified step by step guidance1
Step 1: Understand the concept of nuclear stability. The stability of a nucleus is determined by the balance between protons and neutrons. A stable nucleus has a neutron-to-proton ratio close to 1:1 for light elements (Z<20) and 1.5:1 for heavy elements (Z>20).
Step 2: Consider the neutron-to-proton ratio. The isotope Q is said to have an unfavorable neutron-to-proton ratio, which typically means it has either too many or too few neutrons compared to protons. This would usually make the nucleus unstable.
Step 3: Reflect on the half-life of the isotope. Despite the unfavorable ratio, isotope Q has a very long half-life, which indicates it is quite stable. This is unusual and suggests there must be another factor contributing to its stability.
Step 4: Consider the concept of 'magic numbers' in nuclear physics. These are specific numbers of protons or neutrons in a nucleus that result in increased stability. These numbers are 2, 8, 20, 28, 50, 82, and 126 for both protons and neutrons.
Step 5: Propose a reason for the unusual stability. It's possible that isotope Q has a 'magic number' of protons or neutrons, which could explain its stability despite the unfavorable neutron-to-proton ratio.
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Key Concepts
Here are the essential concepts you must grasp in order to answer the question correctly.
Isotopes and Stability
Isotopes are variants of a chemical element that have the same number of protons but different numbers of neutrons. The stability of an isotope is influenced by its neutron-to-proton ratio; typically, a ratio close to 1:1 is considered stable. However, some isotopes can exhibit unusual stability despite having unfavorable ratios due to factors such as nuclear shell effects or the presence of magic numbers of nucleons, which can lead to increased binding energy.
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Isotopes
Half-Life
Half-life is the time required for half of the atoms in a radioactive sample to decay. It is a crucial concept in nuclear chemistry, as it provides insight into the stability and longevity of isotopes. A long half-life, such as that of isotope Q, suggests that the isotope undergoes decay processes very slowly, which can be attributed to its unique nuclear structure or energy levels that resist decay.
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Nuclear Reactions
Nuclear reactions involve the transformation of atomic nuclei through processes such as fusion, fission, or radioactive decay. In the context of the question, the collision of 24997Bk with isotope Q leads to the formation of tennessine (294117Ts) and the release of neutrons. Understanding the mechanics of these reactions, including energy considerations and conservation laws, is essential for analyzing the stability and behavior of the resulting isotopes.
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Related Practice
Textbook Question
Nuclear scientists have synthesized approximately 1600 nuclei not known in nature. More might be discovered with heavy-ion bombardment using high-energy particle accelerators. Complete and balance the following reactions, which involve heavy-ion bombardments:
(a) 63Li + 5628Ni → ?
(b) 4020Ca + 24896Cm → 14762Sm + ?
(c) 8838Sr + 8436Kr → 11646Pd + ?
(d) 4020Ca + 23892U → 7030Zn + 4 10n + 2 ?
Textbook Question
In 2010, a team of scientists from Russia and the United States reported creation of the first atom of element 117, which is named tennessine, and whose symbol is Ts. The synthesis involved the collision of a target of 24997Bk with accelerated ions of an isotope which we will denote Q. The product atom, which we will call Z, immediately releases neutrons and forms 294117Ts: 24997Bk + Q → Z → 294117Ts + 3 10n (a) What are the identities of isotopes Q and Z? (c) Collision of ions of isotope Q with a target was also used to produce the first atoms of livermorium, Lv. The initial product of this collision was 296116Lv. What was the target isotope with which Q collided in this experiment?