Question

Make a simple sketch of the shape of the main part of the periodic table, as shown (a) Ignoring \(\mathrm{H}\) and \(\mathrm{He}\), write a single straight arrow from the element with the smallest bonding atomic radius to the element with the largest. (b) Ignoring \(\mathrm{H}\) and \(\mathrm{He}\), write a single straight arrow from the element with the smallest first ionization energy to the element with the largest. (c) What significant observation can you make from the arrows you drew in parts (a) and (b)? [Sections \(7.3\) and 7.4]

Short answer

In summary, the element with the smallest bonding atomic radius is Fluorine (F) and the element with the largest atomic radius is Francium (Fr). The element with the smallest first ionization energy is Francium (Fr) and the element with the largest first ionization energy is Fluorine (F). The significant observation we can make from the arrows is that they point in the same direction, indicating that trends in bonding atomic radius and first ionization energy are inversely related: as atomic radius decreases, ionization energy increases. This inverse relationship is attributed to the increased effective nuclear charge experienced by electrons as we move across a period and the overall increase in the number of electron shells as we move down a group.

Step-by-step solution

Sketch the main part of the periodic table

To draw a simple sketch of the main part of the periodic table, one can use the following outline: ``` --------------------- | 1 | 2 | ... | --------------------- | 3 | 4 | ... | --------------------- | ... | ... | ... | --------------------- ``` Remember that the periodic table is organized in rows (periods) and columns (groups).

Identify the smallest and largest bonding atomic radius

In general, atomic radius decreases from left to right across a period and increases from top to bottom within a group. Thus, the element with the smallest bonding atomic radius will be found in the top-right corner of the periodic table, while the element with the largest atomic radius will be found in the bottom-left corner. Ignoring Hydrogen and Helium, the top-right element is Fluorine (F), and the bottom-left element is Francium (Fr).

Draw an arrow between the smallest and largest bonding atomic radius

Now, we will draw a single straight arrow from Fluorine (F) to Francium (Fr) to represent the trend in bonding atomic radius.

Identify the smallest and largest first ionization energy

Ionization energy generally increases from left to right across a period and decreases from top to bottom within a group. Hence, the element with the smallest first ionization energy can be found in the bottom-left corner of the periodic table, whereas the element with the largest first ionization energy is located in the top-right corner. Ignoring Hydrogen and Helium, the bottom-left element is Francium (Fr), and the top-right element is Fluorine (F).

Draw an arrow between the smallest and largest first ionization energy

We will now draw a single straight arrow from Francium (Fr) to Fluorine (F) to represent the trend in first ionization energy.

Make a significant observation from the arrows

The significant observation we can make from the arrows is that they point in the same direction. This suggests that trends in bonding atomic radius and first ionization energy are, in general, inversely related: as the atomic radius decreases, the ionization energy increases. These trends can be attributed to the increased effective nuclear charge experienced by electrons as we move across a period, and the overall increase in the number of electron shells as we move down a group.

Key concepts

Atomic Radius

The atomic radius is a measure of the size of an atom, which gives us an idea of how far the outer electrons are from the nucleus. In the periodic table, you'll notice that the atomic radius changes systematically. Moving from left to right across a period, the atomic radius tends to decrease. This happens because more protons are being added to the nucleus, strengthening the pull on the outer electrons and drawing them closer.

On the other hand, when you go down a group, the atomic radius increases. Why? As you descend, new electron shells are added to the atom, increasing its size. The outermost electrons are further from the nucleus with every added shell, which contributes to a larger atomic radius.

• Smallest atomic radius: top-right of the periodic table.
• Largest atomic radius: bottom-left of the periodic table.

Understanding atomic radius is essential because it affects how atoms interact and bond with each other.

Ionization Energy

Ionization energy refers to the energy required to remove an electron from an atom or ion. This property is crucial for understanding an element's reactivity. Across the periodic table, ionization energy exhibits a recognizable trend.

As you move from left to right across a period, ionization energy increases. The increasing number of protons enhances the effective nuclear charge, making it more difficult to remove an electron. Conversely, as you move down a group, the ionization energy decreases. Additional electron shells reduce the hold of the nucleus on the outermost electron, making it easier to remove.

• Lowest ionization energy: bottom-left of the periodic table.
• Highest ionization energy: top-right of the periodic table.

These trends are pivotal for understanding why certain elements, particularly those on the right side of the periodic table, are less likely to lose electrons and form positive ions.

Trends in Periodic Table

The periodic table is a remarkable chart that reveals many chemical properties of elements based on their positions. One of the key trends it displays is how atomic properties change in a predictable pattern. This consistency is driven by the number of protons and electron configurations.

The trends observed include:

• Decrease in atomic radius from left to right across a period due to increasing effective nuclear charge.
• Increase in atomic radius down a group because of added electron shells.
• Increase in ionization energy from left to right, for the same reason that the effective nuclear charge increases.
• Decrease in ionization energy down a group, due to the added distance of outer electrons from the nucleus.

The predictable nature of these trends makes the periodic table a vital tool in chemistry, simplifying predictions about element behavior.

Effective Nuclear Charge

Effective nuclear charge ( extit{Z_{ ext{eff}}} ) is the net positive charge experienced by valence electrons in an atom. It helps explain why trends in the periodic table happen. As you move across a period, the effective nuclear charge increases. This is due to added protons that increase the nucleus's pull on electrons.

Even though electrons are added, the increase in protons is more significant, drawing the negatively charged electrons closer and reducing atomic radius. Furthermore, an increase in effective nuclear charge means more energy is required to remove an electron, explaining the rise in ionization energy across a period.

• A higher effective nuclear charge pulls outer electrons closer.
• This increased pull explains the trend toward smaller atomic radii and higher ionization energies.

Effective nuclear charge is thus central to the understanding of periodic trends, tightly linking atomic structure to elemental properties.