Why is the electron affinity of each group 5A element more positive than that of each corresponding group 4A element? Use the outer electron configurations for these columns to suggest a reason for this observation.

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Identify the outer electron configurations for Group 4A and Group 5A elements. Group 4A elements have the general outer electron configuration of \( ns^2 np^2 \), while Group 5A elements have \( ns^2 np^3 \).

Understand electron affinity: it is the energy change when an electron is added to a neutral atom in the gas phase, forming a negative ion. A more negative electron affinity indicates a greater tendency to gain an electron.

Consider the stability of half-filled orbitals. Group 5A elements have half-filled \( p \) orbitals (\( np^3 \)), which are relatively stable due to electron pairing and exchange energy.

Adding an electron to a Group 5A element results in a \( np^4 \) configuration, which is less stable than the half-filled \( np^3 \) configuration, making the electron affinity less negative (more positive).

In contrast, Group 4A elements, with \( np^2 \) configuration, gain stability when an electron is added to form \( np^3 \), resulting in a more negative electron affinity compared to Group 5A.

Key Concepts

Here are the essential concepts you must grasp in order to answer the question correctly.

Electron Affinity

Electron affinity is the energy change that occurs when an electron is added to a neutral atom in the gas phase. A more positive electron affinity indicates that the atom releases more energy upon gaining an electron, making it more favorable for the atom to accept an electron. This property is influenced by the atom's electron configuration and its ability to stabilize the added electron.

Group 4A and 5A Elements

Group 4A elements, such as carbon and silicon, have four valence electrons, while Group 5A elements, like nitrogen and phosphorus, have five. The additional valence electron in Group 5A elements allows them to achieve a more stable electron configuration (octet) upon gaining an electron, which contributes to their higher electron affinity compared to Group 4A elements.

Outer Electron Configuration

The outer electron configuration refers to the arrangement of electrons in the outermost shell of an atom. For Group 4A elements, the outer configuration is ns²np², while for Group 5A elements, it is ns²np³. The presence of an unpaired electron in Group 5A elements allows for greater stability and energy release when an additional electron is added, leading to a more positive electron affinity.

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Electron Configuration Example

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