31.3 Substructure of the nucleus (Page 4/16)

College physics Page 4 / 16

The fact that nuclear forces are very strong is responsible for the very large energies emitted in nuclear decay. During decay, the forces do work, and since work is force times the distance ( $W = Fd cos θ$ ), a large force can result in a large emitted energy. In fact, we know that there are two distinct nuclear forces because of the different types of nuclear decay—the strong nuclear force is responsible for $α$ decay, while the weak nuclear force is responsible for $β$ decay.

The many stable and unstable nuclei we have explored, and the hundreds we have not discussed, can be arranged in a table called the chart of the nuclides , a simplified version of which is shown in [link] . Nuclides are located on a plot of $N$ versus $Z$ . Examination of a detailed chart of the nuclides reveals patterns in the characteristics of nuclei, such as stability, abundance, and types of decay, analogous to but more complex than the systematics in the periodic table of the elements.

A chart of nuclides is shown with x axis labeled as number of protons or atomic number with range zero to one hundred ten and y axis labeled as number of neutrons with range zero to one hundred sixty. A straight dashed line is shown for equal atomic number and number of nuclides. A number of points are plotted above the dashed line. The region up to atomic number eighty and neutron number one hundred thirty is shown as stable nuclei and above this region is unstable nuclei. — Simplified chart of the nuclides, a graph of $N$ versus $Z$ for known nuclides. The patterns of stable and unstable nuclides reveal characteristics of the nuclear forces. The dashed line is for $N = Z$ . Numbers along diagonals are mass numbers $A$ .

In principle, a nucleus can have any combination of protons and neutrons, but [link] shows a definite pattern for those that are stable. For low-mass nuclei, there is a strong tendency for $N$ and $Z$ to be nearly equal. This means that the nuclear force is more attractive when $N = Z$ . More detailed examination reveals greater stability when $N$ and $Z$ are even numbers—nuclear forces are more attractive when neutrons and protons are in pairs. For increasingly higher masses, there are progressively more neutrons than protons in stable nuclei. This is due to the ever-growing repulsion between protons. Since nuclear forces are short ranged, and the Coulomb force is long ranged, an excess of neutrons keeps the protons a little farther apart, reducing Coulomb repulsion. Decay modes of nuclides out of the region of stability consistently produce nuclides closer to the region of stability. There are more stable nuclei having certain numbers of protons and neutrons, called magic numbers . Magic numbers indicate a shell structure for the nucleus in which closed shells are more stable. Nuclear shell theory has been very successful in explaining nuclear energy levels, nuclear decay, and the greater stability of nuclei with closed shells. We have been producing ever-heavier transuranic elements since the early 1940s, and we have now produced the element with $Z = 118$ . There are theoretical predictions of an island of relative stability for nuclei with such high $Z$ s.

Portrait of Maria Goeppert Mayer — The German-born American physicist Maria Goeppert Mayer (1906–1972) shared the 1963 Nobel Prize in physics with J. Jensen for the creation of the nuclear shell model. This successful nuclear model has nucleons filling shells analogous to electron shells in atoms. It was inspired by patterns observed in nuclear properties. (credit: Nobel Foundation via Wikimedia Commons)

Section summary

Two particles, both called nucleons, are found inside nuclei. The two types of nucleons are protons and neutrons; they are very similar, except that the proton is positively charged while the neutron is neutral. Some of their characteristics are given in [link] and compared with those of the electron. A mass unit convenient to atomic and nuclear processes is the unified atomic mass unit (u), defined to be
$1 u = 1.6605 \times 10^{- 27} kg = 931.46 MeV / c^{2} .$
A nuclide is a specific combination of protons and neutrons, denoted by
$_{Z}^{A} X_{N} or simply^{A} X,$
$Z$ is the number of protons or atomic number, X is the symbol for the element, $N$ is the number of neutrons, and $A$ is the mass number or the total number of protons and neutrons,
$A = N + Z .$
Nuclides having the same $Z$ but different $N$ are isotopes of the same element.
The radius of a nucleus, $r$ , is approximately
$r = r_{0} A^{1 / 3},$
where $r_{0} = 1.2 fm$ . Nuclear volumes are proportional to $A$ . There are two nuclear forces, the weak and the strong. Systematics in nuclear stability seen on the chart of the nuclides indicate that there are shell closures in nuclei for values of $Z$ and $N$ equal to the magic numbers, which correspond to highly stable nuclei.

Conceptual questions

The weak and strong nuclear forces are basic to the structure of matter. Why we do not experience them directly?

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Define and make clear distinctions between the terms neutron, nucleon, nucleus, nuclide, and neutrino.

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What are isotopes? Why do different isotopes of the same element have similar chemistries?

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Problems&Exercises

Verify that a $2 . 3 \times 10^{17} kg$ mass of water at normal density would make a cube 60 km on a side, as claimed in [link] . (This mass at nuclear density would make a cube 1.0 m on a side.)

\begin{array}{l} m = ρV = {ρd}^{3} & \Rightarrow & a = {(\frac{m}{ρ})}^{1/3} = {(\frac{2.3 \times 10^{17} kg}{1000 {kg/m}^{3}})}^{\frac{1}{3}} \\ = & 61 \times 10^{3} m = 61 km \end{array}

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Find the length of a side of a cube having a mass of 1.0 kg and the density of nuclear matter, taking this to be $2.3 \times 10^{17} {kg/m}^{3}$ .

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What is the radius of an $α$ particle?

$1.9 fm$

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Find the radius of a $^{238} Pu$ nucleus. $^{238} Pu$ is a manufactured nuclide that is used as a power source on some space probes.

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(a) Calculate the radius of $^{58} Ni$ , one of the most tightly bound stable nuclei.

(b) What is the ratio of the radius of $^{58} Ni$ to that of $^{258} Ha$ , one of the largest nuclei ever made? Note that the radius of the largest nucleus is still much smaller than the size of an atom.

(a) $4.6 fm$

(b) $0 . 61 to 1$

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The unified atomic mass unit is defined to be $1 u = 1 . 6605 \times 10^{−27} kg$ . Verify that this amount of mass converted to energy yields 931.5 MeV. Note that you must use four-digit or better values for $c$ and $∣ q_{e} ∣$ .

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What is the ratio of the velocity of a $β$ particle to that of an $α$ particle, if they have the same nonrelativistic kinetic energy?

$85 . 4 to 1$

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If a 1.50-cm-thick piece of lead can absorb 90.0% of the $γ$ rays from a radioactive source, how many centimeters of lead are needed to absorb all but 0.100% of the $γ$ rays?

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The detail observable using a probe is limited by its wavelength. Calculate the energy of a $γ$ -ray photon that has a wavelength of $1 \times 10^{- 16} m$ , small enough to detect details about one-tenth the size of a nucleon. Note that a photon having this energy is difficult to produce and interacts poorly with the nucleus, limiting the practicability of this probe.

$12.4 GeV$

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(a) Show that if you assume the average nucleus is spherical with a radius $r = r_{0} A^{1 / 3}$ , and with a mass of $A$ u, then its density is independent of $A$ .

(b) Calculate that density in ${u/fm}^{3}$ and ${kg/m}^{3}$ , and compare your results with those found in [link] for $^{56} Fe$ .

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What is the ratio of the velocity of a 5.00-MeV $β$ ray to that of an $α$ particle with the same kinetic energy? This should confirm that $β$ s travel much faster than $α$ s even when relativity is taken into consideration. (See also [link] .)

19.3 to 1

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(a) What is the kinetic energy in MeV of a $β$ ray that is traveling at $0.998 c$ ? This gives some idea of how energetic a $β$ ray must be to travel at nearly the same speed as a $γ$ ray. (b) What is the velocity of the $γ$ ray relative to the $β$ ray?

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Questions & Answers

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When MP₁ becomes negative, TP start to decline. Extuples Suppose that the short-run production function of certain cut-flower firm is given by: Q=4KL-0.6K2 - 0.112 • Where is quantity of cut flower produced, I is labour input and K is fixed capital input (K-5). Determine the average product of lab

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Extuples Suppose that the short-run production function of certain cut-flower firm is given by: Q=4KL-0.6K2 - 0.112 • Where is quantity of cut flower produced, I is labour input and K is fixed capital input (K-5). Determine the average product of labour (APL) and marginal product of labour (MPL)

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In economics, the contract curve refers to the set of points in an Edgeworth box diagram where both parties involved in a trade cannot be made better off without making one of them worse off. It represents the Pareto efficient allocations of goods between two individuals or entities, where neither p

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Suppose a consumer consuming two commodities X and Y has The following utility function u=X0.4 Y0.6. If the price of the X and Y are 2 and 3 respectively and income Constraint is birr 50. A,Calculate quantities of x and y which maximize utility. B,Calculate value of Lagrange multiplier. C,Calculate quantities of X and Y consumed with a given price. D,alculate optimum level of output .

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Answer

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the market for lemon has 10 potential consumers, each having an individual demand curve p=101-10Qi, where p is price in dollar's per cup and Qi is the number of cups demanded per week by the i th consumer.Find the market demand curve using algebra. Draw an individual demand curve and the market dema

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suppose the production function is given by ( L, K)=L¼K¾.assuming capital is fixed find APL and MPL. consider the following short run production function:Q=6L²-0.4L³ a) find the value of L that maximizes output b)find the value of L that maximizes marginal product

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Source: OpenStax, College physics. OpenStax CNX. Jul 27, 2015 Download for free at http://legacy.cnx.org/content/col11406/1.9

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