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Chapter 6: Problem 103

Scientists have speculated that element 126 might have a moderate stability, allowing it to be synthesized and characterized. Predict what the condensed electron configuration of this element might be.

Short Answer

Expert verified
The predicted condensed electron configuration for element 126 is \[ \text{Rn} \ 7s^2 \ 5f^14 \ 6d^10 \ 7p^14. \]

Step by step solution

01

Identify the Previous Noble Gas

Before we can start building the electron configuration, we need to determine which noble gas element comes before element 126 in the periodic table. This will be the starting point for our electron configuration. The last noble gas with a lower atomic number than 126 is Radon (Rn), which has atomic number 86. So our starting point will be Rn.
02

Build the Electron Configuration

Starting with Rn as our base, we will add electrons one at a time, following the Aufbau principle. This principle states that electrons are added to orbitals of lower energy first, then orbitals of higher energy.
03

Step 2.1: Add Electrons to the 7s Orbital

After Rn, the next lowest energy orbital is the 7s orbital. A maximum of two electrons can occupy an s orbital. Thus, we add two electrons to the 7s orbital: Rn 7s^2
04

Step 2.2: Add Electrons to the 5f Orbital

The 5f orbital has a capacity for 14 electrons. After filling the 7s orbital, we add 14 electrons to the 5f orbital: Rn 7s^2 5f^14
05

Step 2.3: Add Electrons to the 6d Orbital

Moving on to the 6d orbital, it has a capacity for 10 electrons. We add 10 electrons to the 6d orbital: Rn 7s^2 5f^14 6d^10
06

Step 2.4: Add Electrons to the 7p Orbital

Finally, we reach the 7p orbital. Up to this point, we have already assigned (86 + 2 + 14 + 10) = 112 electrons. Since element 126 has 126 electrons, we need to add 14 more electrons to complete its electron configuration: Rn 7s^2 5f^14 6d^10 7p^14 In conclusion, the predicted condensed electron configuration for element 126 is \[ \text{Rn} \ 7s^2 \ 5f^14 \ 6d^10 \ 7p^14. \]

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Most popular questions from this chapter

The familiar phenomenon of a rainbow results from the diffraction of sunlight through raindrops. (a) Does the wavelength of light increase or decrease as we proceed out-wavelength of light increase or decrease as we proceed out- frequency of light increase or decrease as we proceed out-ward? [Section 6.3]

The following electron configurations represent excited states. Identify the element and write its ground-state condensed electron configuration. (a) \(1 s^{2} 2 s^{2} 2 p^{4} 3 s^{1},\) (b) \([\) Ar \(] 4 s^{1} 3 d^{10} 4 p^{2} 5 p^{1}\) \((\mathbf{c})[\mathrm{Kr}] 5 s^{2} 4 d^{2} 5 p^{1}\)

For orbitals that are symmetric but not spherical, the contour representations (as in Figures 6.23 and 6.24 ) suggest where nodal planes exist (that is, where the electron density is zero). For example, the \(p_{x}\) orbital has a node wherever \(x=0\) . This equation is satisfied by all points on the \(y z\) plane, so this plane is called a nodal plane of the \(p_{x}\) orbital. (a) Determine the nodal plane of the \(p_{z}\) orbital. (b) What are the two nodal planes of the \(d_{x y}\) orbital? (c) What are the two nodal planes of the \(d_{x^{2}-y^{2}}\) orbital?

Write the condensed electron configurations for the following atoms, using the appropriate noble-gas core abbreviations: (a) \(\mathrm{Cs},(\mathbf{b}) \mathrm{Ni},(\mathbf{c}) \mathrm{Se},(\mathbf{d}) \mathrm{Cd},(\mathbf{e}) \mathrm{U},(\mathbf{f}) \mathrm{Pb}\)

Using Heisenberg's uncertainty principle, calculate the uncertainty in the position of (a) a 1.50-mg mosquito moving at a speed of 1.40 \(\mathrm{m} / \mathrm{s}\) if the speed is known to within \(\pm 0.01 \mathrm{m} / \mathrm{s}\) ; (b) a proton moving at a speed of \((5.00 \pm 0.01) \times 10^{4} \mathrm{m} / \mathrm{s}\) . (The mass of a proton is given in the table of fundamental constants in the inside cover of the text.)
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