ELECTRONIC STRUCTURE OF MATTER GRADE 9

ROXANNE AQUINO

5 Dec 202114:45

Summary

TLDRIn this educational broadcast, Grade 9 students are introduced to the quantum mechanical model of the atom. The lesson builds on previous atomic models, exploring how electrons are distributed across orbitals and energy levels. Students engage in activities to understand electron behavior, the uncertainty of their position, and the principles that govern electron configuration, including the Aufbau principle, Pauli’s exclusion principle, and Hund’s rule. Through hands-on practice, such as identifying atomic models and writing electronic configurations, students gain a deeper understanding of atomic structure and the fundamental principles that describe it.

Takeaways

😀 The lesson focuses on understanding the quantum mechanical model of the atom, electron behavior, and electronic configurations.
😀 The quantum mechanical model of the atom evolved from earlier models, including Rutherford's nuclear model and Bohr's planetary model.
😀 The key principles for writing electron configurations are the Aufbau principle, Pauli's exclusion principle, and Hund's rule.
😀 The quantum mechanical model suggests that electrons are found in probability clouds around the nucleus rather than in fixed orbits.
😀 The Heisenberg Uncertainty Principle states that it is impossible to know both the exact position and momentum of an electron simultaneously.
😀 In the quantum mechanical model, electrons exist in orbitals, which have specific shapes and energy values.
😀 The principal energy levels of an atom are labeled as shells (n), which contain sub-levels (s, p, d, f).
😀 The maximum number of electrons that can occupy a principal energy level is given by the formula 2n², where 'n' is the principal quantum number.
😀 The Aufbau principle explains that electrons fill orbitals in order of increasing energy, starting with the lowest energy orbitals.
😀 Pauli's exclusion principle states that two electrons can occupy the same orbital only if they have opposite spins.
😀 Hund's rule dictates that electrons will fill degenerate orbitals singly before pairing to minimize repulsion between electrons.
😀 The activity examples help students apply the principles of atomic structure by writing the electron configurations of elements in the periodic table.

Q & A

What is the quantum mechanical model of the atom?
-The quantum mechanical model describes the atom as having a nucleus at the center, with electrons moving in regions of space around the nucleus called atomic orbitals. These orbitals are described using wave functions, and the exact position of an electron cannot be precisely determined, only the probability of finding it in certain regions.
How does the Rutherford atomic model differ from the quantum mechanical model?
-Rutherford's model depicted the atom as mostly empty space with electrons orbiting in fixed orbits around a dense nucleus. In contrast, the quantum mechanical model rejects fixed orbits, treating electrons as wave-like entities within atomic orbitals, and it incorporates the uncertainty principle.
What are atomic orbitals and how are they shaped?
-Atomic orbitals are regions in space around the nucleus where electrons are likely to be found. They have specific shapes, such as spherical (s orbitals), dumbbell-shaped (p orbitals), and more complex shapes (d and f orbitals).
Who were the key scientists behind the development of the quantum mechanical model?
-The quantum mechanical model was developed by scientists such as Louis de Broglie, Erwin Schrödinger, and Werner Heisenberg. De Broglie proposed that electrons exhibit both particle and wave properties, Schrödinger developed a mathematical equation to describe the hydrogen atom, and Heisenberg formulated the uncertainty principle.
What does Heisenberg's uncertainty principle state?
-Heisenberg's uncertainty principle states that it is impossible to simultaneously know both the exact position and momentum of a very small particle, such as an electron, with complete certainty.
What is the significance of the Schrödinger equation in the quantum mechanical model?
-The Schrödinger equation provides a mathematical framework to describe the behavior of electrons in atoms. It helps determine the probability distribution of electrons within atomic orbitals.
What are the three main principles used to write electron configurations?
-The three main principles are: 1) **Aufbau Principle** – electrons occupy orbitals in order of increasing energy; 2) **Pauli Exclusion Principle** – two electrons can occupy the same orbital only if they have opposite spins; 3) **Hund's Rule** – electrons fill degenerate orbitals singly first before pairing.
What does the Aufbau principle state about electron arrangement?
-The Aufbau principle states that electrons will fill orbitals starting from the lowest energy level before occupying higher energy orbitals.
How are orbitals in the quantum mechanical model different from those in earlier atomic models?
-In earlier models like Rutherford's, electrons were thought to move in fixed orbits. However, in the quantum mechanical model, orbitals are regions of space where electrons are most likely to be found, and their exact positions cannot be precisely determined.
How is the electron configuration of an element written?
-Electron configuration is written by distributing electrons across different orbitals and sublevels in order of increasing energy, following the principles of the Aufbau principle, Pauli Exclusion principle, and Hund's Rule. For example, sodium (Na) with atomic number 11 has the configuration 1s² 2s² 2p⁶ 3s¹.