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Examples - Nuclear Fission and Fusion - Nuclear Spectroscopy, Inorganic Chemistry, CSIR-NET | Chemistry for EmSAT Achieve PDF Download

Example 1.

Write a balanced nuclear equation to describe each reaction

a. the beta decay of  Examples - Nuclear Fission and Fusion - Nuclear Spectroscopy, Inorganic Chemistry, CSIR-NET | Chemistry for EmSAT Achieve

b. the decay of Examples - Nuclear Fission and Fusion - Nuclear Spectroscopy, Inorganic Chemistry, CSIR-NET | Chemistry for EmSAT Achieve by electron capture

c. the decay of  Examples - Nuclear Fission and Fusion - Nuclear Spectroscopy, Inorganic Chemistry, CSIR-NET | Chemistry for EmSAT Achieve by positron emission

Given: radioactive nuclide and mode of decay

Asked for: balanced nuclear equation

Strategy:

A Identify the reactants and the products from the information given.

B Use the values of A and Z to identify any missing components needed to balance the equation.

Solution:

a.

A We know the identities of the reactant and one of the products (a β particle). We can therefore begin by writing an equation that shows the reactant and one of the products and indicates the unknown product as  Examples - Nuclear Fission and Fusion - Nuclear Spectroscopy, Inorganic Chemistry, CSIR-NET | Chemistry for EmSAT Achieve

Examples - Nuclear Fission and Fusion - Nuclear Spectroscopy, Inorganic Chemistry, CSIR-NET | Chemistry for EmSAT Achieve

B Because both protons and neutrons must be conserved in a nuclear reaction, the unknown product must have a mass number of A = 35 − 0 = 35 and an atomic number of Z = 16 − (−1) = 17. The element with Z = 17 is chlorine, so the balanced nuclear equation is as follows:

Examples - Nuclear Fission and Fusion - Nuclear Spectroscopy, Inorganic Chemistry, CSIR-NET | Chemistry for EmSAT Achieve

b.

A We know the identities of both reactants:  Examples - Nuclear Fission and Fusion - Nuclear Spectroscopy, Inorganic Chemistry, CSIR-NET | Chemistry for EmSAT Achieve and an inner electron, e-1. The reaction is as follows:

Examples - Nuclear Fission and Fusion - Nuclear Spectroscopy, Inorganic Chemistry, CSIR-NET | Chemistry for EmSAT Achieve

B Both protons and neutrons are conserved, so the mass number of the product must be A = 201 + 0 = 201, and the atomic number of the product must be Z = 80 + (−1) = 79, which corresponds to the element gold. The balanced nuclear equation is thus

Examples - Nuclear Fission and Fusion - Nuclear Spectroscopy, Inorganic Chemistry, CSIR-NET | Chemistry for EmSAT Achieve

c.

A As in part (a), we are given the identities of the reactant and one of the products—in this case, a positron. The unbalanced nuclear equation is therefore

Examples - Nuclear Fission and Fusion - Nuclear Spectroscopy, Inorganic Chemistry, CSIR-NET | Chemistry for EmSAT Achieve

B The mass number of the second product is A = 30 − 0 = 30, and its atomic number is = 15 − 1 = 14, which corresponds to silicon. The balanced nuclear equation for the reaction is as follows:

Examples - Nuclear Fission and Fusion - Nuclear Spectroscopy, Inorganic Chemistry, CSIR-NET | Chemistry for EmSAT Achieve

 

Example 2.

Predict the kind of nuclear change each unstable nuclide undergoes when it decays.

Examples - Nuclear Fission and Fusion - Nuclear Spectroscopy, Inorganic Chemistry, CSIR-NET | Chemistry for EmSAT Achieve

Given: nuclide

Asked for: type of nuclear decay

Strategy:

Based on the neutron-to-proton ratio and the value of Z, predict the type of nuclear decay reaction that will produce a more stable nuclide.

Solution:

a. This nuclide has a neutron-to-proton ratio of only 1.05, which is much less than the requirement for stability for an element with an atomic number in this range. Nuclei that have low neutron-to-proton ratios decay by converting a proton to a neutron. The two possibilities are positron emission, which converts a proton to a neutron and a positron, and electron capture, which converts a proton and a core electron to a neutron. In this case, both are observed, with positron emission occurring about 86% of the time and electron capture about 14% of the time.

b. Nuclei with Z > 83 are too heavy to be stable and usually undergo alpha decay, which decreases both the mass number and the atomic number. Thus  Examples - Nuclear Fission and Fusion - Nuclear Spectroscopy, Inorganic Chemistry, CSIR-NET | Chemistry for EmSAT Achieve  is expected to decay by alpha emission.

c. This nuclide has a neutron-to-proton ratio of 1.4, which is very high for a light element. Nuclei with high neutron-to-proton ratios decay by converting a neutron to a proton and an electron. The electron is emitted as a β particle, and the proton remains in the nucleus, causing an increase in the atomic number with no change in the mass number. We therefore predict that  Examples - Nuclear Fission and Fusion - Nuclear Spectroscopy, Inorganic Chemistry, CSIR-NET | Chemistry for EmSAT Achieve   will undergo beta decay.

d. This is a massive nuclide, with an atomic number of 100 and a mass number much greater than 200. Nuclides with A ≥ 200 tend to decay by alpha emission, and even heavier nuclei tend to undergo spontaneous fission. We therefore predict that  Examples - Nuclear Fission and Fusion - Nuclear Spectroscopy, Inorganic Chemistry, CSIR-NET | Chemistry for EmSAT Achieve will decay by either or both of these two processes. In fact, it decays by both spontaneous fission and alpha emission, in a 97:3 ratio.

 

Example 3.

In 1933, Frédéric Joliot and Iréne Joliot-Curie (daughter of Marie and Pierre Curie) prepared the first artificial radioactive isotope by bombarding aluminum-27 with α particles. For each 27Al that reacted, one neutron was released. Identify the product nuclide and write a balanced nuclear equation for this transmutation reaction.

Given: reactants in a nuclear transmutation reaction

Asked for: product nuclide and balanced nuclear equation

Strategy:

A Based on the reactants and one product, identify the other product of the reaction. Use conservation of mass and charge to determine the values of Z and A of the product nuclide and thus its identity.

B Write the balanced nuclear equation for the reaction.

Solution:

A Bombarding an element with α particles usually produces an element with an atomic number that is 2 greater than the atomic number of the target nucleus. Thus we expect that aluminum (= 13) will be converted to phosphorus (= 15). With one neutron released, conservation of mass requires that the mass number of the other product be 3 greater than the mass number of the target. In this case, the mass number of the target is 27, so the mass number of the product will be 30. The second product is therefore phosphorus-30, 3015P1530P.

B The balanced nuclear equation for the reaction is as follows:

Examples - Nuclear Fission and Fusion - Nuclear Spectroscopy, Inorganic Chemistry, CSIR-NET | Chemistry for EmSAT Achieve

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FAQs on Examples - Nuclear Fission and Fusion - Nuclear Spectroscopy, Inorganic Chemistry, CSIR-NET - Chemistry for EmSAT Achieve

1. What is nuclear fission?
Ans. Nuclear fission is a process in which the nucleus of an atom is split into two or more smaller nuclei, along with the release of a large amount of energy. This process is usually achieved by bombarding the atom with a neutron, causing it to become unstable and split.
2. What is nuclear fusion?
Ans. Nuclear fusion is a process in which two or more atomic nuclei combine to form a larger nucleus, resulting in the release of a significant amount of energy. This process occurs at extremely high temperatures and pressures, such as those found in the core of the sun, where hydrogen nuclei combine to form helium.
3. How is nuclear spectroscopy used in the study of nuclear reactions?
Ans. Nuclear spectroscopy is a technique used to study the structure and properties of atomic nuclei. It involves the analysis of the electromagnetic radiation emitted or absorbed by the nuclei during a nuclear reaction. By studying the emitted radiation, scientists can gather valuable information about the energy levels, spin, and other characteristics of the nuclei involved in the reaction.
4. What are the applications of inorganic chemistry in the field of nuclear science?
Ans. Inorganic chemistry plays a crucial role in the field of nuclear science. It is used to study the properties and behavior of inorganic compounds that are important in nuclear reactions, such as radioactive isotopes, nuclear fuels, and nuclear waste materials. Inorganic chemists also develop and optimize materials for nuclear reactors and contribute to the development of new nuclear technologies.
5. What is CSIR-NET EmSAT Achieve?
Ans. CSIR-NET (Council of Scientific and Industrial Research-National Eligibility Test) EmSAT Achieve is an exam conducted by CSIR in India to determine the eligibility of candidates for Junior Research Fellowship (JRF) and lectureship in the field of science and technology. It assesses the candidates' knowledge and understanding of various scientific concepts, including subjects like inorganic chemistry, nuclear spectroscopy, and nuclear science.
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