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Chapter 40: Q75P (page 1251)

Suppose that the electron had no spin and that the Pauli exclusion principle still held .Which, if any, of the present noble gases would remain in that category?

Short Answer

Expert verified

The noble gas that would remain in that category is Argon.

Step by step solution

01

The given data

a) The electron has no spin.

b) The Pauli鈥檚 exclusion principle is still held.

02

Understanding the concept of the spin degree of freedom:

According to Pauli's Exclusion Principle, no two electrons in the same atom may have the same values for all four of their quantum numbers.

After the removal of the spin value, the spin degree of freedom becomes half of the electron states for each shell would become half as Pauli's Exclusion Principle is still applied. Now, comparing the electron states after the removal of other electron states from the shell and before removal, we can get the noble gas that maintains its configuration.

03

Calculation of the configuration of the noble gas that is maintained:

Without the spin degree of freedom, the number of available electron states for each shell would be reduced by half. So, the values of for the noble gas elements would become half of what they are now: Z=1,5,9,18,27and43.

Of this set of numbers, the only one that coincides with one of the familiar noble gas atomic numbers Z=2,10,18,36,54and86is18.

Hence, the noble gas that would be the only one to remain 鈥渘oble鈥 is Argon.

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Most popular questions from this chapter

A hypothetical atom has only two atomic energy levels, separated by 32 eV . Suppose that at a certain altitude in the atmosphere of a star there are 6.11013/cm3of these atoms in the higher-energy state and 2.51015/cm3in the lower-energy state. What is the temperature of the star鈥檚 atmosphere at that altitude?

Determine the constant C in Eq. 40-27 to five significant figures by finding in terms of the fundamental constants in Eq. 40-24 and then using data from Appendix B to evaluate those constants. Using this value of in Eq. 40-27, determine the theoretical energy Etheoryof the Kphoton for the low-mass elements listed in the following table. The table includes the value (eV) of the measured energy Eexpof the Kphoton for each listed element. The percentage deviation between Etheoryand Eexpcan be calculated as:

percentagedeviation=Etheory-EexpEexp100

What is the percentage deviation for (a) Li, (b) Be, (c) B, (d) C, (e) N, (f) O, (g) F, (h) Ne, (i) Na, and (j) Mg?

(There is actually more than one Kray because of the splitting of the energy level, but that effect is negligible for the elements listed here.)

The binding energies of K-shell and L-shell electrons in copper are 8.979 keV and 0.951 keV, respectively. If a Kx-ray from copper is incident on a sodium chloride crystal and gives a first-order Bragg reflection at an angle of 74.1 measured relative to parallel planes of sodium atoms, what is the spacing between these parallel planes?

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(a) Rank the three points according to the energy Uof the electron鈥檚 intrinsic magnetic dipole moment s, most positive first.

(b) What is the direction of the force on the electron due to the magnetic field if the spin-up electron is at point 2?

The active medium in a particular laser generates laser light at a wavelength of 694nm is 6.00 cm long and 1.00 cm in diameter. (a) Treat the medium as an optical resonance cavity analogous to a closed organ pipe. How many standing-wave nodes are there along the laser axis? (b) By what amountfwould the beam frequency have to shift to increase this number by one? (c) Show that fis just the inverse of the travel time of laser light for one round trip back and forth along the laser axis. (d) What is the corresponding fractional frequency shift f/f? The appropriate index of refraction of the lasing medium (a ruby crystal) is 1.75.
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