12.1/S1.3.6 Evidence of Energy Levels by 1st I.E. Trends Across a Period [HL IB Chemistry]

Richard Thornley

5 Jun 201205:30

Summary

TLDRThis video discusses the first ionization energies of elements in Period 3 of the periodic table, explaining how the energy required to remove an electron varies. It highlights trends from sodium, with the lowest ionization energy, to argon, with the highest. Key concepts of stability in electron configurations are emphasized, showcasing how elements with stable orbitals require less energy to ionize. The presenter navigates through specific elements, pointing out exceptions and explaining the influence of nuclear charge and atomic structure on ionization energy, making the content informative and engaging for viewers.

Takeaways

😀 The first ionization energy is the minimum energy required to remove an electron from a gaseous atom.
🔋 Sodium has the lowest first ionization energy in period three, making its 3s electron the easiest to remove.
🔼 Magnesium's higher nuclear charge results in a slightly higher first ionization energy compared to sodium.
💡 Aluminium's 3p electron is easier to remove than expected due to the stability of the electron configuration.
📉 Silicon requires more energy to remove its 3p electron because of a higher nuclear charge.
⚖️ Phosphorus has a stable half-filled 3p orbital, complicating the trend and requiring more energy to remove an electron.
✨ Sulfur's electron removal leads to a stable half-filled 3p configuration, requiring less energy than anticipated.
🌌 The trend of increasing ionization energy continues with chlorine, as more protons increase electron attraction.
🔒 Argon has the smallest atomic radius and highest nuclear charge in period three, requiring the most energy for electron removal.
😴 The speaker expresses boredom and a lack of motivation while discussing these concepts, indicating a sense of repetitiveness in the material.

Q & A

What is the first ionization energy?
-The first ionization energy is the minimum energy required to remove an electron from a gaseous atom.
Which element in period three has the lowest first ionization energy?
-Sodium has the lowest first ionization energy in period three, making it the easiest element to remove an electron from.
Why is sodium's electron the easiest to remove?
-Sodium's electron is the easiest to remove because it is furthest from the nucleus, resulting in weaker attraction to the nucleus.
How does the first ionization energy change across period three?
-As you move across period three from sodium to argon, the first ionization energy generally increases due to the increasing nuclear charge.
What trend is observed for magnesium's first ionization energy compared to sodium's?
-Magnesium has a higher first ionization energy than sodium because it has a higher nuclear charge, resulting in a stronger attraction to its valence electron.
What role do sub-levels play in the ionization energies of elements like aluminum?
-In aluminum, the electron is removed from the 3p sub-level, which is surprisingly easier to remove than expected due to the stability associated with empty or half-filled orbitals.
What is the significance of stable half-filled orbitals in ionization energy?
-Stable half-filled orbitals, such as those in phosphorus, can make it less energy-intensive to remove an electron, as the removal leads to a more stable electronic configuration.
How does the electron configuration of sulfur affect its ionization energy?
-For sulfur, removing an electron results in a stable half-filled 3p configuration, making it energetically favorable and requiring less energy than expected.
What is observed for chlorine in terms of ionization energy trends?
-Chlorine continues the trend of increasing ionization energy across period three due to the increasing nuclear charge, making it harder to remove an electron.
What explains the high ionization energy of argon?
-Argon has the highest ionization energy in period three because it has the smallest atomic radius and the most protons, resulting in a strong attraction for its valence electrons.